KR102536739B1 - Air conditioning system with evaporative humidifier - Google Patents

Abstract

The present invention provides an air conditioning system combined with an evaporative humidifier which controls humidity by evaporating and cooling water and has a detailed configuration, particularly including a dispersion unit for dispersing evaporated indoor air and a buffer unit for attenuating vibration.

Description

Air conditioning system with evaporative humidifier}

The present invention relates to an air conditioning system incorporating an evaporative humidifier, and more particularly, to an evaporative humidifier that controls humidity by evaporating and cooling water, and its detailed components, particularly a dispersing unit that disperses vaporized indoor air It relates to an air conditioning system grafted with an evaporative humidifier equipped with a buffer unit for damping vibration.

In general, in an air conditioning system used for constant temperature and humidity in an indoor space such as a computer room, it is common to operate the air conditioning system using a steam injection humidifier.

However, in general, air conditioning systems have significantly lower energy consumption than other types of humidifiers in the indoor space, so an efficient evaporative humidifier is additionally provided to perform humidification. A humidifier of an up-flow type that discharges upward is used.

Therefore, the present invention uses an evaporative humidifier, but circulates the water used and disperses it finely to facilitate vaporization, thereby reducing the economic cost for humidification and presenting an air conditioning system that can expect an energy saving effect. do.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an air conditioning system incorporating an evaporative humidifier equipped with an evaporative humidifier for evaporating and cooling water to adjust humidity.

Another object of the present invention is to provide an air conditioning system grafted with an evaporative humidifier having a supply unit, a passage unit, an injection unit, and a discharge unit.

Another object of the present invention is to provide an air conditioning system grafted with an evaporative humidifier having a dispersing unit for finely dispersing vaporized indoor air.

Another object of the present invention is to provide an air conditioning system grafted with an evaporative humidifier equipped with a buffer unit for damping vibration of a dispersing unit.

The object of the present invention is not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

An air conditioning system grafted with an evaporative humidifier according to an embodiment of the present invention for solving the above problems may include an evaporative humidifier that controls humidity by evaporating and cooling water.

In one embodiment, the evaporative humidifier includes a supply unit for introducing indoor air to vaporize and cool it, a passage unit integrally connected to one side of an upper portion of the supply unit and delivering the vaporized indoor air by the supply unit, and the passage unit a spraying part integrally communicated with the passage to move the vaporized indoor air delivered by the passage part downward, and integrally communicated with both lower sides of the spraying part to discharge the vaporized indoor air moved by the spraying part into the room. It may include an outlet.

In one embodiment, the supply unit includes a filter unit installed on one side to remove dust from the inflow indoor air, a water supply unit installed on an upper portion to supply moisture to the indoor air that has passed through the filter unit, and the water supply unit. A dispersing unit for distributing and pre-treating indoor air supplied with moisture to vaporize, a evaporation unit built in the lower part to vaporize the indoor air that has passed through the dispersing unit, and a lower part installed to store moisture remaining in the supply unit; A cooling unit may be included to cool indoor air that has passed therethrough.

In one embodiment, the water supply unit stores wastewater and is equipped with a pump to supply wastewater to a wastewater tank, a water purification unit to purify wastewater supplied from the wastewater tank, a water purification tank to store purified water from the water purification unit, and the water purification unit. A purified water supply unit may be included to supply water to indoor air from the purified water stored in the tank.

In one embodiment, the passage part includes a fan installed at one side to generate an air current to move the vaporized indoor air, and the spraying part to move the vaporized indoor air moved by the fan downward. The exhaust unit may include a flow guide member that distributes the vaporized indoor air moved by the compression injection unit into two directions.

In one embodiment, the dispersion unit, a rotary motor that is driven to generate rotational force, a body head coupled to the rotational motor and having a through hole in the central portion, inserted into the through hole of the body head to transmit the rotational force generated by the rotational motor A rotating member, a central portion through which the rotating member is coupled, a cover portion coupled to the body head, a unit body coupled to the cover portion and having an open front, and a rotating wing portion rotatably seated on the unit body; A precision dispersing unit installed at the upper front end of the unit body to precisely disperse the vaporized indoor air, a braking member inserted in the lower portion of the unit body to control the braking of the rotary wing unit, and a vaporized indoor air installed at the rear of the unit body. A dispersion plate formed with a plurality of dispersion holes for dispersing indoor air, a pinion gear and a linear gear rotatably fastened to the rotary wing on the lower part of the unit body and rotating in mesh with each other, and installed on the upper part of the body head for rotational operation It may include a buffer unit that attenuates the vibration generated by preventing deviation from the position.

In one embodiment, the rotary wing unit is inserted into the unit body, is rotatably fastened to the pinion gear and the linear gear, and rotates by the rotational force of the rotary member; It may include a plurality of wings formed along the wing, and precision protrusions formed on a surface of one of the plurality of wings to precisely disperse the vaporized indoor air.

In one embodiment, the precision dispersion unit includes a precision wing portion rotating in contact with the precision protrusion, and a precision dispersion plate formed to seat the precision wing unit, wherein the dispersion unit rotates by a rotational force generated by the rotation motor. The method may further include a feature of dispersing vaporized indoor air passing through the precision blades by contacting with each other while the rotational blades rotate as the member rotates.

In one embodiment, the shock absorber unit includes a plurality of fixing rods installed on the top of the body head, a lower rotating drum having fixing protrusions rotatably fastened while being supported by the plurality of fixing rods, and rotatable on the plurality of fixing rods. A lower braking drum installed on the top of the lower rotating drum to brake the rotation of the lower rotating drum while being installed on the lower rotating drum, a plurality of upper rotating drums having fixing protrusions rotatably fastened while being rotatably supported by the plurality of fixing rods, a plurality of An upper braking drum rotatably installed on the holder of the dog and installed below the upper rotary drum to brake the rotation of the upper rotary drum, fixed inside the evaporative humidifier and on one side of the upper rotary drum A driving motor installed to generate and transmit rotational force, a conveyor belt provided to surround the upper rotary drum and the lower rotary drum, and a plurality of conveyor belts installed on an upper surface of the conveyor belt to dampen vibration generated by operating the dispersion unit A buffer may be included.

In one embodiment, the plurality of buffer units may include a sucker unit attached to the top surface of the body head while sucking in air through an air flow hole, and a buffer control unit inserted into the sucker unit and adjusting the buffering operation of the sucker unit. can

In one embodiment, the buffer control unit, a plurality of side wings extending outward so as to be inserted into the sucker portion are formed at the bottom and the inside is vented, the control unit body is built into the control unit body and generates an elastic force to dampen vibration A buffer spring, a spring fixing member to be inserted to fix the buffer spring protrudes downward, a second intermediate body having a cylindrical shape, and a first intermediate body having a cylindrical shape having fastening teeth formed on the lower portion of the second intermediate body to be fastened to the upper portion of the second intermediate body. , A fastening member formed with a plurality of protruding wings downward so as to be fastened to the upper part of the control unit body, and an adjustment unit head formed to be fastened to the upper part of the control unit body while being inserted and fastened with the fastening member.

In one embodiment, in the buffer unit, the sucker part is adsorbed on the top of the distributing part to damp vibration generated by a rotational motion in the buffer adjusting part, and when the sucker part is detached by the vibration, the drive motor operates to It may further include a feature of rotating the conveyor belt with an upper rotating drum to dispose of the sucker unit so that it is sucked.

According to the present invention, an evaporative humidifier that controls humidity by evaporating and cooling water, and its detailed components, in particular, an evaporative humidifier equipped with a dispersion unit for dispersing vaporized indoor air and a buffer unit for damping vibration A grafted air conditioning system is provided. Effects according to the present invention are not limited by the contents exemplified above, and more various effects are included in the present invention.

1 shows an overall embodiment of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
2 illustrates a connection relationship between a water supply unit and a cooling unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
Figure 2a shows a detailed relationship diagram of the moisture supply unit of the air conditioning system to which the evaporative humidifier according to the present invention is grafted.
3 shows an overall embodiment of a dispersion unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
4 is an assembly view of a dispersion unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
5 shows an overall embodiment of a buffer unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
6 illustrates embodiments of a buffer unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.
7 is an assembly view of a buffer control unit of an air conditioning system to which an evaporative humidifier according to the present invention is grafted.

Hereinafter, various embodiments will be described in more detail with reference to the accompanying drawings. The embodiments described in this specification may be modified in various ways. Certain embodiments may be depicted in the drawings and described in detail in the detailed description. However, specific embodiments disclosed in the accompanying drawings are only intended to facilitate understanding of various embodiments. Therefore, the technical idea is not limited by the specific embodiments disclosed in the accompanying drawings, and it should be understood to include all equivalents or substitutes included in the spirit and technical scope of the invention.

Terms including ordinal numbers, such as first and second, may be used to describe various components, but these components are not limited by the above terms. The terminology described above is only used for the purpose of distinguishing one component from another.

In this specification, terms such as "comprise" or "having" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded. It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be. On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle.

Meanwhile, a “module” or “unit” for a component used in this specification performs at least one function or operation. And a "module" or "unit" may perform a function or operation by hardware, software, or a combination of hardware and software. In addition, a plurality of “modules” or “units” other than “modules” or “units” to be executed in specific hardware or to be executed in at least one processor may be integrated into at least one module. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be abbreviated or omitted.

1 shows an overall embodiment of an air conditioning system to which an evaporative humidifier 10 according to the present invention is grafted.

Referring to FIG. 1 , the air conditioning system to which the evaporative humidifier 10 is grafted may include the evaporative humidifier 10 that controls humidity by evaporating and cooling water.

The evaporative humidifier 10 may include a supply unit 20 , a passage unit 30 , a spray unit 40 , and a discharge unit 50 .

The supply unit 20 may be provided to vaporize and cool indoor air by introducing it.

The passage part 30 may be integrally communicated with one upper side of the supply part 20 to deliver indoor air vaporized by the supply part 20 .

The injection unit 40 may be integrally communicated with the passage unit 30 to move the vaporized indoor air transmitted through the passage unit 30 downward.

The discharge unit 50 may be integrally communicated with both lower sides of the spray unit 40 to discharge vaporized indoor air moved by the spray unit 40 into the room.

In particular, the supply unit 20 may include a filter unit 21, a water supply unit 22, a dispersion unit 100, a vaporization unit 23, and a cooling unit 24.

The filter unit 21 may be installed on one side to supply clean air by removing dust from the introduced indoor air.

At this time, the filter unit 21 may be provided in a shape equipped with a conventional ACID filter or an organic filter, but is not limited thereto.

The moisture supply unit 22 may be provided to supply moisture to indoor air that has passed through the filter unit 21 by being installed on the upper portion.

At this time, the water supply method can be supplied in various ways, such as dripping water, spraying, or a method of mixing the two.

Referring to FIG. 2A , the water supply unit 22 may include a waste water tank 221, a water purification unit 222, a purified water tank 223, and a purified water supply unit 224.

The wastewater tank 221 may store wastewater and may be equipped with a pump to supply wastewater.

The water purification unit 222 may be provided to purify wastewater supplied from the wastewater tank 221 .

The purified water tank 223 may be provided to store purified water purified by the water purifying unit 222 .

The purified water supply unit 224 may supply purified water stored in the purified water tank 223 to indoor air as moisture.

Accordingly, in the prior art, since water supplied from a water supply pipe is used, constant water must be continuously supplied, so that energy costs can be reduced by using wastewater through the above configurations.

The dispersion unit 100 may be provided to disperse and pre-process the indoor air supplied with moisture by the water supply unit 22 so as to facilitate vaporization.

In order to facilitate vaporization, it reflects the conventional phenomenon that the smaller the surface area of water droplets, the faster they vaporize.

The vaporizing unit 23 may be provided to vaporize indoor air that has passed through the dispersion unit 100 and is built into the lower portion.

At this time, the vaporizing unit 23 may operate to emit heat by itself to heat and vaporize indoor air containing moisture.

The cooling unit 24 may be installed at a lower portion to store moisture remaining in the supply unit 20 and to cool indoor air passing through the dispersion unit 100 .

2 shows a connection relationship between a water supply unit 22 and a cooling unit 24 of an air conditioning system to which an evaporative humidifier 10 according to the present invention is grafted.

Referring to FIG. 2, the water supply unit 22 and the cooling unit 24 are connected to each other by a connecting pipe such as a pipe, so that the water stored in the cooling unit 24 is controlled to move to the water supply unit 22 and supplied thereto. .

As a result, movement of water between the water supply unit 22 and the cooling unit 24 is circulated, so that water can be used economically.

Meanwhile, the passage part 30 may include a fan 31 installed on one side to generate airflow to move the vaporized indoor air.

The spraying unit 40 may include a compression spraying unit 41 that sprays compressed air to move the vaporized indoor air moved by the fan 31 downward.

The discharge unit 50 may include a flow guide member 51 distributing the vaporized indoor air moved by the compression injection unit 41 in both directions, that is, in both directions.

The assembly relationship according to the above configurations and the effect of the embodiment are described in detail as follows.

In the evaporative humidifier 10, the supply unit 20, the passage unit 30, the spray unit 40, and the discharge unit 50 are integrally connected and assembled.

In the supply unit 20, indoor air passes through the filter unit 21, the water supply unit 22, the dispersing unit 100, and the vaporization unit 23 in order to purify the air and then vaporize it.

The water supply unit 22 is preferably installed at the top for dripping or downward spraying, but is not limited thereto.

Indoor air containing harmful substances such as fine dust and dust is filtered through the filter unit 21 .

Moisture is supplied to indoor air through the moisture supply unit 22 to increase humidity.

Indoor air containing moisture is finely dispersed through the dispersing unit 100 to narrow the surface area, leading to an effect of facilitating vaporization.

It is preferable that the evaporation unit 23 is built in the lower part so that its operation does not overlap with the cooling unit 24 .

Heat is supplied to the dispersed indoor air through the vaporizing unit 23 to vaporize it.

The fan 31 of the passage part 30 operates to form an air current that moves the vaporized indoor air along the passage part 30 .

The compression spraying unit 41 of the spraying unit 40 sprays compressed air to move the indoor air flow downward.

The moved indoor air moves to the discharge unit 50, passes through the flow guide member 51, is dispersed in both directions, and is discharged into the room.

This has the effect of increasing the humidity in the indoor space by discharging high-humidity airflow.

In addition, the room air vaporized through the vaporizing unit 23 and the moisture remaining without being vaporized through the vaporizing unit 23 are cooled by operating the cooling unit 24 .

This has the effect of lowering the humidity in the indoor space by not discharging high-humidity airflow.

On the other hand, the water cooled by the cooling unit 24 can move to the water supply unit 22 mutually, so that there is an economic effect of effectively using the water by circulating it.

By replacing the conventional steam injection humidifier with the evaporative humidifier 10, water is evaporated to raise the humidity or cooled to lower the humidity, so there is an energy saving effect without using additional energy.

3 and 4 show an overall embodiment and an assembly view of the dispersion unit 100 of the air conditioning system to which the evaporative humidifier 10 according to the present invention is grafted.

3 and 4, the dispersion unit 100 includes a rotary motor 110, a body head 120, a rotary member 130, a cover part 140, a unit body 150, and a rotary wing part 160. ), a precision dispersion unit 170, a braking member 180, a dispersion plate 190, a pinion gear 200, a linear gear, and a buffer unit 300.

The rotation motor 110 may be provided to drive to generate rotational force.

At this time, the rotary motor 110 is not limited to the installation position, but it is preferable to be installed so as to be built in the same way as the vaporization unit 23 in appearance.

The body head 120 may be coupled to the rotary motor 110 and provided with a central portion through which it is formed.

The rotation member 130 may be inserted into the through hole of the body head 120 to transmit rotational force generated by the rotation motor 110 .

The cover part 140 may have a central portion through which the rotating member 130 is fastened, and is fastened with the body head 120 .

The unit body 150 may be coupled to the cover part 140 and provided such that the front is opened.

The rotary wing unit 160 may be provided to rotatably seat on the open shape of the unit body 150 .

In addition, the rotary wing 160 may include a rotary shaft 161, a wing 162, and a precision protrusion 163.

The rotating shaft 161 may be inserted into the unit body 150 and rotatably engaged with the pinion gear 200 and the linear gear 210 .

In addition, a plurality of rotational shafts 161 may be provided to rotate by the rotational force of the rotational member 130 .

At this time, the number of rotation shafts 161 may be installed differently depending on the width of the unit body 150, and two are shown in the drawing.

A plurality of wings 162 may be formed along the circumference of the plurality of rotation shafts 161 .

The wings 162 serve to disperse the vaporized indoor air passing through the dispersing unit 100 by rotating along the rotating shaft 161 .

The precision protrusion 163 may be formed on the surface of one of the plurality of wing parts 162 to precisely disperse the vaporized indoor air.

In addition, the precise protrusion 163 precisely disperses the vaporized indoor air through a coordinated operation with the precise dispersion unit 170 .

The precision dispersion unit 170 may be installed at the upper front end of the unit body 150 to precisely disperse the vaporized indoor air.

In addition, the precision dispersion unit 170 may include a precision wing unit 171 and a precision dispersion plate 172 .

The precision wing part 171 may be provided to rotate in contact with the precision protrusion 163 .

The precision dispersion plate 172 may be provided in a plate shape so that the precision wings 171 are seated thereon.

The braking member 180 may be inserted into the lower portion of the unit body 150 to control the braking of the rotary wing unit 160 .

The dispersion plate 190 may be installed at the rear of the unit body 150 to form a plurality of dispersion holes 191 distributing vaporized indoor air.

The pinion gear 200 and the linear gear 210 may be rotatably coupled to the rotary wing 160 at the lower part of the unit body 150 and rotated in engagement with each other.

The shock absorber unit 300 may be installed on the top of the body head 120 to dampen vibration generated by a rotational motion to prevent deviation from position.

The assembly relationship according to the above configurations and the effect of the embodiment are described in detail as follows.

Based on the unit body 150, the rotary blade 160 is seated inside, and the precision dispersion unit 170 is assembled thereon.

In addition, the pinion gear 200 and the linear gear 210 are rotatably assembled with the rotary shaft 161 of the rotary wing 160 at the lower part of the unit body 150.

In addition, the distribution plate 190 is assembled to the rear part of the unit body 150.

In addition, the cover part 140, the rotating member 130, and the body head 120 are sequentially assembled on the upper part of the unit body 150.

In addition, a braking member 180 is assembled to brake the rotary wing 160 on one side of the unit body 150 .

In the dispersion unit 100, the rotary member 130 rotates by the rotational force generated by the rotary motor 110, and the rotary wing 160 rotates while the precision wing 171 contacts and rotates.

This rotation operation has the effect of pre-processing the vaporized indoor air passing through the dispersion unit 100 to finely disperse the surface area to facilitate vaporization.

Indoor air passing through the rotary wing 160 has an effect of being secondarily dispersed by the dispersion holes 191 of the dispersion plate 190 .

5 to 7 show overall embodiments and assembly views of a buffer unit 300 and its lower components of an air conditioning system to which the vaporizing humidifier 10 according to the present invention is grafted.

5 to 7, the buffer unit 300 includes a fixing table 310, a lower rotary drum 320, a lower drum drum 330, an upper rotary drum 340, an upper drum drum 350, a driving motor. 360, a conveyor belt 370, and a buffer 380 may be included.

The buffer unit 300 is preferably installed so as to be built into the upper part of the position where the distributing unit 100 is installed, where the externally installed position is desirable.

Therefore, as shown in FIG. 1, the buffer unit 300 may be installed to be embedded between the water supply unit 22 and the fan 31, whereby the buffer unit 300 is connected to the water supply unit 22 and the fan. It is also possible to add a role to attenuate the impact applied to (31).

A plurality of fixing units 310 may be provided to be installed above the body head 120 .

In the drawing, two fixing tables 310 are installed on both sides, but it is not limited to the drawing in order to increase the fixing force using a plurality of fixing tables 310 .

The lower rotating drum 320 may be provided with fixing protrusions 321 rotatably engaged while being supported by a plurality of fixing tables 310 formed on both sides.

The lower braking drum 330 may be rotatably installed on the plurality of fixtures 310 and installed on top of the lower rotary drum 320 to brake the rotation of the lower rotary drum 320 .

At this time, the lower braking drum 330 may be supported on the fixing table 310 by having fixing protrusions formed on both sides like the lower rotating drum 320 .

The upper rotating drum 340 may be provided with fixing protrusions 341 rotatably fastened while being rotatably supported by a plurality of fixing tables 310 formed on both sides.

The upper braking drum 350 may be rotatably installed on the plurality of fixtures 310 and may be installed under the upper rotating drum 340 to brake the rotation of the upper rotating drum 340 .

At this time, the upper braking drum 350 may be supported on the fixing table 310 by having fixing protrusions formed on both sides like the upper rotating drum 340 .

The driving motor 360 may be installed on one side of the upper rotary drum 340 while being fixed or embedded inside the evaporative humidifier 10 to generate and transmit rotational force.

The conveyor belt 370 may be provided to surround the upper rotary drum 340 and the lower rotary drum 320 .

A plurality of buffer units 380 may be installed on the top surface of the conveyor belt 370 to dampen vibrations generated when the dispersion unit 100 operates.

In addition, the plurality of buffer units 380 may include a sucker unit 381 and a buffer control unit 382 .

The sucker unit 381 may be attached to the top surface of the body head 120 while sucking air through the air flow hole 381a.

The buffer controller 382 may be inserted into the sucker unit 381 to adjust the buffer operation of the sucker unit 381 .

In addition, the buffer control unit 382 includes the control unit body 3821, the buffer spring 3822, the second intermediate body 3823, the first intermediate body 3824, the fastening member 3825, and the control unit head 3826. ) may be included.

The control unit body 3821 may have a cylindrical shape with a plurality of side wings 3821a extending outward to be inserted into the sucker unit 381 and having a through-hole inside.

The buffer spring 3822 may be built into the control unit body 3821 and may be provided to damp vibration by generating an elastic force.

The second intermediate body 3823 may have a cylindrical shape in which a spring fixing member 3823a to be inserted to fix the buffer spring 3822 protrudes downward.

The first intermediate body 3824 may be provided in a cylindrical shape with fastening teeth 3824a formed at the lower portion to be fastened to the upper portion of the second intermediate body 3823.

The fastening member 3825 may be provided so that a plurality of protruding wings are formed so as to be fastened to the upper portion of the control unit body 3821 .

The adjusting unit head 3826 may be formed to be fastened to an upper portion of the adjusting unit body 3821 while being inserted into and fastened with the fastening member 3825 .

The assembly relationship according to the above configurations and the effect of the embodiment are described in detail as follows.

Based on the upper part of the dispersion unit 100, a plurality of fixing units 310 are assembled at a predetermined interval.

The lower rotary drum 320 , the lower brake drum 330 , the upper brake drum 350 , and the upper rotary drum 340 are sequentially assembled to the fixing table 310 .

A driving motor 360 generating rotational force is assembled to one side of the upper rotating drum 340 .

A conveyor belt 370 is assembled to surround the lower rotary drum 320 and the upper rotary drum 340 .

Meanwhile, in order to brake the upper rotary drum 340 and the lower rotary drum 320, the upper drum 350 and the lower drum 330 rotate in opposite directions to the respective drums to brake them.

A plurality of shock absorbers 380 are assembled on the top surface of the conveyor belt 370 at regular intervals.

In the buffer unit 380, a sucker unit 381 and a buffer control unit 382 are assembled on the sucker unit 381.

The buffer control unit 382 includes a buffer spring 3822, a second intermediate body 3823, and a first intermediate body 3824 based on the control unit body 3821 on which a plurality of side wings are formed to be assembled to the sucker unit 381. ), the fastening member 3825, and the control unit head 3826 are assembled in this order.

The shock absorber unit 300 has an effect of attenuating the vibration generated by the rotation of the sucker unit 381 adsorbed on the top of the dispersion unit 100 by the shock absorber control unit 382 .

As shown in the drawing, the sucker unit 381 is attached while adsorbing air through the air flow port 381a.

In addition, when the sucker unit 381 is detached due to vibration, the driving motor 360 operates to rotate the conveyor belt 370 with the upper rotating drum 340 to move another sucker unit 381 to the distributing unit 100. There is an advantage in that it can be placed and adsorbed to provide a continuous buffering effect.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those with knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

Evaporative Humidifier(10)
Supply (20)
Filter part (21)
Moisturizer (22)
Vaporizing part (23)
Cooling unit (24)
Passage (30)
fan(31)
Injection part (40)
Compression injection part (41)
Discharge (50)
Flow guide member (51)
Distributing unit (100)
Rotary Motor (110)
body head(120)
Rotating member (130)
cover part 140
unit body (150)
Rotary wing (160)
rotary shaft(161)
wing part (162)
Precision projection (163)
precision dispersing unit (170)
Precision wings (171)
Precision Dispersion Plate(172)
Braking member (180)
Dispersion Plate(190)
Dispersion Ball(191)
Pinion Gear(200)
Linear Gear(210)
buffer unit (300)
Fixture(310)
Lower rotating drum (320)
Fixed protrusion (321)
Lower brake drum (330)
Upper rotating drum (340)
Fixed protrusion (341)
Upper brake drum (350)
drive motor(360)
Conveyor Belt(370)
Buffer part (380)
sucker part(381)
Air flow port (381a)
Buffer control unit 382
Adjustment body (3821)
Side Wings (3821a)
Buffer Spring (3822)
Second intermediate body 3823
Spring fixing member (3823a)
First intermediate body 3824
Locking Teeth (3824a)
Fastening member (3825)
Protruding Wings (3825a)
Adjuster Head (3826)

Claims (3)

An evaporative humidifier that controls humidity by evaporating and cooling water;
In the air conditioning system to which the evaporative humidifier is grafted,
The vaporizing humidifier,
a supply unit that vaporizes and cools indoor air by introducing it;
a passage part integrally communicating with one side of an upper portion of the supply part to deliver the indoor air vaporized by the supply part;
a spraying unit that communicates integrally with the passage and moves the vaporized indoor air delivered by the passage downward;
a discharge unit integrally communicating with both sides of the lower portion of the spraying unit and discharging the vaporized indoor air moved by the spraying unit into the room;
including,
the supply unit,
a filter unit installed on one side to remove dust from the inflow indoor air;
a moisture supply unit installed on an upper portion to supply moisture to indoor air that has passed through the filter unit;
a distributing unit for pre-processing by distributing the indoor air supplied with moisture by the water supply unit to vaporize;
a vaporizing unit installed at a lower portion to vaporize indoor air that has passed through the dispersing unit;
a cooling unit installed at a lower portion to store moisture remaining in the supply unit and to cool indoor air that has passed through the distribution unit;
including,
The water supply unit,
A wastewater tank that stores wastewater and is equipped with a pump to supply wastewater;
a water purifying unit that purifies the waste water supplied from the waste water tank;
a water purification tank storing purified water purified by the water purification unit;
a purified water supply unit supplying moisture to indoor air with the purified water stored in the purified water tank;
including,
the passage,
a fan installed on one side to generate an airflow to move the vaporized indoor air;
including,
the injection part,
a compression spraying unit spraying compressed air to move the vaporized room air moved downward by the fan;
including,
The discharge part,
a flow guide member distributing the vaporized indoor air moved by the compression injection part into two branches;
In the air conditioning system to which the evaporative humidifier is grafted,
The dispersing unit,
a rotational motor that drives to generate a rotational force;
a body head fastened to the rotary motor and having a through-hole in the center;
a rotational member inserted into the through hole of the body head to transmit the rotational force generated by the rotational motor;
a cover portion having a central portion through which the rotating member is fastened and which is fastened to the body head;
a unit body fastened to the cover and having an open front;
Rotating wings rotatably seated on the unit body;
a precision dispersion unit installed at the upper front end of the unit body to precisely disperse the vaporized indoor air;
a braking member inserted into the lower portion of the unit body to control braking of the rotary blade;
a dispersion plate installed at the rear of the unit body and having a plurality of dispersion holes for dispersing vaporized indoor air;
a pinion gear and a linear gear that are rotatably fastened to the rotary wing at a lower portion of the unit body and rotate in engagement with each other;
including,
The rotary wing part,
a plurality of rotational shafts inserted into the unit body, rotatably engaged with the pinion gear and the linear gear, and rotated by the rotational force of the rotational member;
a plurality of wing parts formed along the circumference of the plurality of rotation shafts;
precision protrusions formed on the surface of one of the plurality of wings to precisely disperse the vaporized indoor air;
including,
The precision dispersion unit,
precision blades rotating in contact with the precision protrusions;
a precision dispersion plate formed to seat the precision wings;
including,
The dispersing unit,
The rotary member is rotated by the rotational force generated by the rotary motor and the rotary wing rotates while the precision wing rotates in contact with each other to disperse vaporized indoor air passing through. Evaporation type humidifier grafted air conditioning system. delete delete

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