KR20200072692A - Spraying device for spraying deodorant using microorganisms - Google Patents

Abstract

The present invention relates to a spray device for spraying a deodorant using microorganisms. More particularly, the present invention relates to a deodorant spray device for spraying a deodorant using natural microorganisms to reduce odors generated in an air conditioner. To this end, in order to reduce odor in the air conditioner, the deodorant is put into the deodorant spray device and is sprayed to the air conditional. The deodorant is sprayed over the wide area, and odor is favorably removed, thereby creating a pleasant environment.

Description

Injection device for spraying deodorants using microorganisms {omitted}

The present invention relates to an injector for injecting a deodorant using microorganisms, and more particularly, to a deodorant injector for injecting a deodorant using natural microorganisms to reduce odor generated in an air conditioner.

Clean air is recognized as a basis for human health and well-being, and unpleasant odor or polluted air is a major factor that interferes with a pleasant environment. Unsatisfactory air quality in closed conditions is caused by two important factors: One is the indoor air pollutant directly generated from the constituent substances themselves (buildings, vehicles, etc.) constituting the enclosed environment, and the other factor is the odor caused by substances generated by human activities or introduced from outside. .

On the other hand, the air conditioning system is a system that lowers the indoor temperature and optimizes the indoor environment by aiming at air conditioning that harmonizes air temperature, humidity, airflow, and cleanliness in buildings, vehicles, railroads, ships, and aircraft. Such air-conditioning systems are increasing in penetration rate due to the improvement of living standards. Although the basic function has been developed a lot due to the increase in the penetration rate of the air conditioning system, there are still many problems to be solved as an environmental aspect for indoor air quality.

It is known that the cause of the smell of air conditioning, one of the air conditioning systems, is due to the metabolites of fungi and bacteria.

Due to the structure of the air conditioning system, all air passes through the EVA core. When heat exchanges between cold refrigerant and air, condensation condensation occurs according to the temperature difference on the surface of the EVA core. And an environment in which bacteria can live and reproduce. When mold and bacteria grow on the EVA core exposed to outside air, volatile organic compounds (mVOCs) of microorganisms are generated as metabolites of bacteria grown on the EVA core surface, and air passing through the EVA core is blown indoors. When this occurs, the volatile organic compounds generated by the microorganisms may cause the indoors to be exposed to odors caused by mold and bacteria during long-term use.

In order to remove the odor, various types of fragrances are commercially available, but this does not fundamentally remove fungi and bacteria inhabiting the evacore and is only a role of temporarily diluting an unpleasant odor. There have been no cases in which the field was developed specifically to act on specific microorganisms inhabiting Evacore.

Patent registration number 10-1412692 (2014.06.20)

An object of the present invention is to spray the deodorant to a wide area by spraying the air conditioner with a deodorant in a deodorant spraying device to reduce the odor of the air conditioner to smoothly remove the odor.

In order to solve the above problems, the present invention is a deodorant is introduced and stored therein, some of the stored deodorant is compressed by a piston formed therein to move the body portion 110 for moving to the injection unit 130; The handle 120 is located on the upper side of the body portion 110 and the injection switch 121 for turning on/off the spraying operation of the deodorant through the body portion 110; An injection unit 130 connected to one side of the body unit 110 and formed in a tube shape so that the deodorant compressed from the body unit 110 is sprayed to the outside; A control unit 150 located on one side of the body portion 110 to control the operation of the body portion 110 for injection of a deodorant; A power switch 160 positioned on one side of the body part to turn on/off the power of the device; Included on the one side of the body portion 110, the battery 170 is formed with a charging terminal 174 to enable charging; including, the body portion 110 is formed on the inner side of the body portion 110 Deodorant storage unit 111 for storing the deodorant is introduced and stored through the inlet 111a formed on one side; A deodorant flow meter 112 located inside the deodorant storage unit 111 and measuring a flow rate of the deodorant input to the deodorant storage unit 111; A buoyancy sensor 113 which is located inside the deodorant storage unit 111 and checks the flow rate of the deodorant stored in the deodorant storage unit 111 to transmit a signal on whether the deodorant is supplied to the deodorant compression unit 115; It is located between the deodorant storage unit 111 and the deodorant compression unit 115, the supply passage 114 for moving the deodorant from the deodorant storage unit 111 to the deodorant compression unit 115; The deodorant stored in the deodorant storage unit 111 is moved by the piston operation formed on one side according to the on/off operation of the injection switch 121 of the handle 120, connected to the supply passage 114, and the injection unit ( 130) deodorant compression unit 115 to be supplied to; A discharge passage 116 connected to the deodorant compression unit 115 to receive deodorant from the deodorant compression unit 115 and to move to the deodorant transfer unit 117; The deodorant transfer pipe 117b is formed to be connected to the discharge path 116 to move the deodorant received from the discharge path 116, and a two-way ball valve 117c is formed between the deodorant transfer pipe 117b and the two-way Deodorant moving unit 117a is formed with an electric motor (117a) for controlling the movement of the ball valve (117c); and an injection device for injecting a deodorant utilizing microorganisms, characterized in that it comprises,

The control unit 150 is a battery remaining amount display function for displaying the remaining amount of the battery, the injection time setting function for setting the injection time of the deodorant, the remaining injection time to check the remaining injection time for the set injection time through the injection time setting function A display unit 151 including a confirmation function; It shows the injection pressure, the injection pressure check unit 152 includes a spray pressure control function that allows the user to adjust the pressure in real time the deodorant is sprayed; Spray including a spray completion notification function to notify the completion of the injection when the set injection time is completed through the display unit 151, a flow rate shortage notification function to receive a lack of flow rate signal by the buoyancy sensor 113 to inform the lack of flow rate of the deodorant It provides a spray device for spraying a deodorant utilizing microorganisms, characterized in that it comprises a; status alarm unit (153).

The present invention has an effect of creating a pleasant environment by smoothly removing odors by spraying a deodorant to a wide area by spraying the air conditioner with a deodorant to reduce the odor of the air conditioner.

1 is a view showing the overall appearance of the present invention.
2 is a view showing in detail the internal appearance of the deodorant compression unit of the present invention.
3 is a view showing the operation of the deodorant compression unit of the present invention.
4 is a view showing in detail the internal appearance of the deodorant moving part of the present invention.
5 is an enlarged view of the control unit of the present invention.
6 is a view showing an embodiment of the present invention.
7 is a view showing a state of spraying a deodorant on the air conditioner.

The terms or words used in the present specification and claims should not be interpreted as being limited to ordinary or dictionary meanings, and the inventor can appropriately define the concept of terms in order to best describe his or her invention. Based on the principles, it should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to an injection device (hereinafter referred to as an injection device) for spraying a deodorant using microorganisms, specifically, it is generated in an air conditioner by manufacturing a deodorant using natural microorganisms and putting it in the injection device of the present invention to spray it on the air conditioner There is an effect that the odor to be reduced is reduced.

1 is a view of the injection device 100 of the present invention, its components are the body portion 110, the handle 120, the injection unit 130, the pedestal 140, the control unit 150, the power switch ( 160), including a battery 170.

The description of each component is as follows.

The body portion 110 is stored in the deodorant is injected therein, some of the stored deodorant is to be moved to the injection unit 130 after being compressed by the piston.

The body portion 110 is deodorant storage unit 111, deodorant flow meter 112, buoyancy sensor 113, supply passage 114, deodorant compression unit 115, discharge passage 116, deodorant moving unit 117 It is formed including.

Deodorant storage unit 111 is formed on the inner side of the body portion 110, the deodorant is introduced and stored through the inlet 111a formed on one side.

It is preferable that the opening 111a is a hole for introducing a deodorant from the outside, and an opening/closing lid for opening and closing the opening 111a is further formed.

The deodorant flowmeter 112 is located inside the deodorant storage unit 111 and is for measuring the flow rate of the deodorant input to the deodorant storage unit 111.

It is preferable that the deodorant flow meter 112 has a scale displayed on the surface to measure the flow rate of the deodorant.

The buoyancy sensor 113 is located inside the deodorant storage unit 111 and checks the flow rate of the deodorant stored in the deodorant storage unit 111 to transmit a signal on whether the deodorant is supplied to the deodorant compression unit 115. The buoyancy sensor 113 measures the deodorant flow rate that decreases according to the set deodorant injection time, and is formed to stop the deodorant injection when a certain level is reached.

For example, when the flow rate of the deodorant stored in the deodorant storage unit 111 reaches less than 5% after the deodorant is sprayed for a user-set deodorant injection time, the insufficient flow rate signal is sent to the spray state alarm unit of the control unit 150 ( 153).

The supply passage 114 is located between the deodorant storage unit 111 and the deodorant compression unit 115 and serves as a passage through which the deodorant is moved from the deodorant storage unit 111 to the deodorant compression unit 115.

Deodorant compression unit 115 is connected to the supply passage 114, stored in the deodorant storage unit 111 by the piston operation formed on one side in accordance with the on / off operation of the injection switch 121 of the handle 120 The deodorant is moved and supplied to the injection unit 130.

Figure 2 shows the internal appearance of the deodorant compression unit 115, the deodorant compression unit 115 is a first air compressor (115a), the first pressure pump (115b), the first inlet valve (115c), the first It comprises a discharge valve (115d), a second air compressor (115e), a second pressure pump (115f), a second inlet valve (115g), a second outlet valve (115h).

The first air compressor 115a is formed on one side of the deodorant compressing portion 115 to produce compressed air.

The first air compressor 115a is formed with a first intake port 115a' for sucking air to produce compressed air, and a first exhaust port 115a' for discharging unnecessary gas.

The first compressed air line (L1) is connected to the first air compressor 115a, but is a passage for sending compressed air produced from the first air compressor 115a to the first compressed air pump 115b.

One side of the first pressure pump 115b is connected to the first compressed air line L1 and is hollow inside, and includes a first piston 115b' and a first spring 115b''. .

The first piston 115b' is movably installed inside the first pressure pump 115b, and divides the inside of the hollow into a first chamber C1 and a second chamber C2.

The first spring 115b″ is installed in the first chamber C1 and is formed to elastically support the first piston 115b′ to the other end of the first pressure pump 115b.

The first inlet line (L2) is formed so that one side is connected to the first chamber (C1) side of the first pressure pump (115b) and the other side is connected to the supply passage 114, in the form of a tube having a predetermined thickness, the first 1 The farther away from the pressure transfer pump 115b, the more the cross-sectional area is reduced.

The first inlet valve 115c is located inside the first inlet line L2, but is formed in a shape corresponding to the size of the smallest cross-sectional area of the first inlet line L2. The first inlet valve 115c is moved by the first piston 115b', through which the hole of the first inlet line L2 at the position farthest from the pressure pump 115b is blocked or opened. The shape of the inlet line L3 can be roughly confirmed through FIG. 3, and one hole of the first inlet line L2 may be blocked through the first inlet valve 115c as shown in FIG. 3( b ). In addition, the operation thereof will be described in detail below.

The first outflow line (L3) is formed so that one side is connected to the first chamber (C1) side of the first pressure pump (115b) and the other side is connected to the discharge passage 116, in the form of a tube having a predetermined thickness, the first 1 is formed in a form that the cross-sectional area is reduced as it is adjacent to the pressure pump (115b).

The first outlet valve 115d is located inside the first outlet line L3, but is formed in a shape corresponding to the size of the smallest cross-sectional area of the first outlet line L3. The first drain valve 115d is moved by the first piston 115b', through which the hole of the first drain line L3 adjacent to the pressure pump 115b is blocked or opened. The shape of the first outflow line L3 can be roughly confirmed through FIG. 3, and a hole in one side of the first outflow line L3 can be blocked through the first outflow valve 115d as shown in FIG. 3( a ). . In addition, the operation thereof will be described in detail below.

The first air compressor (115a), the first pressure pump (115b), the first inlet valve (115c), the first outlet valve (115d) is the second air compressor (115e), the second pressure pump (115f), the second The inlet valve 115g and the second outlet valve 115h are each formed in the same shape.

The second air compressor 115e is formed on the other side of the deodorant compressing portion 115 to produce compressed air.

The second air compressor 115e is formed with a second intake port 115e' for sucking air to produce compressed air, and a second exhaust port 115e'' for discharging unnecessary gas.

The second compressed air line (L4) is connected to the second air compressor (115e), but is a passage for sending compressed air produced from the second air compressor (115e) to the second compressed air pump (115f).

One side of the second pressure pump 115f is connected to the second compressed air line L4 and is hollow inside, and is formed by including the second piston 115f' and the second spring 115f''. .

The second piston 115f' is movably installed inside the second pressure pump 115f, and divides the inside of the hollow into a third chamber C3 and a fourth chamber C4.

The second spring 115f″ is installed in the third chamber C1 and is formed to elastically support the second piston 115f′ to the other end of the second pressure pump 115f.

The second inlet line (L5) is formed so that one side is connected to the third chamber (C3) side of the second pressure pump (115f) and the other side is connected to the supply passage 114, in the form of a tube having a predetermined thickness, the 2 It is formed in a form in which the cross-sectional area decreases as it moves away from the pressure pump (115f).

The second inlet valve 115g is located inside the second inlet line L5, but is formed in a shape corresponding to the size of the smallest cross-sectional area of the second inlet line L5. The second inlet valve 115g is moved by the second piston 115f', through which the hole of the second inlet line L5 at a position farthest from the second pressure pump 115f is blocked or opened. .

The second discharge line (L6) is formed so that one side is connected to the third chamber (C3) side of the second pressure pump (115f) and the other side is connected to the discharge passage 116, in the form of a tube having a predetermined thickness, the 2 It is formed in a form in which the cross-sectional area is reduced as it is closer to the pressure feeding pump 115f.

The second outlet valve 115h is located inside the second outlet line L6, but is formed in a shape corresponding to the size of the smallest cross-sectional area of the second outlet line L6. The second outlet valve 115h is moved by the second piston 115f', through which the hole of the second outlet line L6 adjacent to the second pressure pump 115f is blocked or opened.

When the deodorant is moved through FIG. 3 in detail, it is as follows.

3 is a first air compressor (115a), the first pressure pump (115b), the first inlet valve (115c), the first outlet valve (115d), the first compressed air line (L1), the first inlet line (L2) ), only the first outflow line (L3) is shown as an example, which is the second air compressor 115e, the second pressure pump 115f, the second intake valve 115g, the second outflow valve 115h, The same applies to the second compressed air line L4, the second inlet line L5, and the second outlet line L6.

Figure 3 (a) is the first air compressor (115a) by pressing the injection switch 121 of the handle 120, the compression pressure is released into the first exhaust port (115a''), thereby causing the first pressure pump (115b) The first piston 115b' of is pulled and moved toward the second chamber C2. At the same time, the pressure inside the first chamber (C1) decreases so that the first inlet valve (115c) moves in the direction of the first chamber (C1), thereby opening the first inlet line (L2), and the deodorant stored from the deodorant storage unit (111). (1) flows down to the first chamber (C1). In addition, the first drain valve 115d is also moved in the direction toward the first chamber C1 to block the hole of the first drain line L3 so that the deodorant 1 is accommodated only in the first chamber C1.

Thereafter, as shown in FIG. 3(b), the first spring 115b″ is compressed by the suction action through the first suction port 115a′ of the first air compressor 115a, and at the same time, the first inlet valve due to the increased internal pressure (115c) is moved in the direction of the deodorant storage unit 111, the hole of the first inlet line L2 is closed, and the first outlet valve 115d is moved in a direction away from the first chamber C1 and the first outlet line The hole of (L3) is opened to move the deodorant to the deodorant moving unit (117).

The first air compressor 115a and the second air compressor 115e are sequentially operated, and the deodorant is compressed by the second air compressor 115e before the compression pressure generated by the first air compressor 115a is exhausted. Since it is started, the user can continuously spray for a set time without stopping the deodorant injection, and the detailed description of the operation of the second air compressor 115e is also the same as in FIG.

The discharge passage 116 is formed to be branched to be connected to the first discharge line L3 and the second discharge line L6 of the deodorant compression part 115, respectively, and the deodorant moving part 117 from the deodorant compression part 115 It is connected to the deodorant moving unit 117 so that the compressed deodorant is moved.

4 is a specific view of the deodorant moving unit 117, the deodorant moving unit 117 is connected to the discharge passage 116, the deodorant received from the deodorant compression unit 115 is moved, the electric motor (117a), It is formed to include a deodorant transfer pipe (117b), a bi-directional ball valve (117c), a ball valve shaft (117d).

Electric motor (117a) is formed on the inner side of the deodorant transfer unit 117 to control the movement of the two-way ball valve (117c).

Deodorant transfer pipe (117b) is connected to the discharge passage 116 on one side and the other side is connected to the injection unit 130 serves to move the deodorant moved from the discharge passage 116 to the injection unit (130).

The two-way ball valve (117c) is formed between the deodorant transfer pipe (117b), the ball valve passage (117c') for moving the deodorant is formed and the movement is controlled by the electric motor (117a) to control the deodorant transfer pipe (117b). Connect or disconnect.

That is, when the user presses the injection switch 121 of the handle 120 as shown in FIG. 4(a), the bi-directional ball valve 117c is moved by the electric motor 117a in a state parallel to the deodorant transfer tube 117b. Deodorant can be connected between the transfer pipe (117b), through which the deodorant can be moved in the direction toward the injection unit 130 (arrow direction). On the other hand, as shown in FIG. 4(a), the bidirectional ball valve 117c is moved so as not to be parallel to the deodorant transfer pipe 117b in the state where the injection switch 121 is off, thereby cutting the deodorant transfer pipe 117b so that the deodorant is sprayed 130 ) Is disconnected.

The ball belt shaft 117d is a shaft supporting the electric motor 117a and the bidirectional ball valve 117c to be connected.

The handle 120 is located on one side of the upper portion of the body portion 110 and the injection switch 121 is formed on one side.

The injection part 130 is connected to one side of the body part 110 and is formed in a tube shape so that the deodorant compressed from the body part 110 is sprayed to the outside.

The pedestal 140 is positioned below the body portion 110 to be supported on the ground.

The control unit 150 is located on one side of the body portion 110 to control the operation of the body portion 110 for injection of the deodorant.

Referring to FIG. 5, the control unit 150 includes a display unit 151, an injection pressure confirmation unit 152, and a spray state alarm unit 153.

The display unit 151 checks the remaining injection time to check the remaining injection time for the set injection time through the battery remaining time display function for displaying the remaining amount of the battery, the injection time setting function for setting the injection time of the deodorant, and the injection time setting function Features and more.

The injection pressure checking unit 152 indicates the injection pressure, and includes an injection pressure control function that allows a user to adjust the pressure at which the deodorant is injected in real time.

The spraying status alarm unit 153 notifies the lack of flow rate of the deodorant by receiving an insufficient flow rate signal by the buoyancy sensor 113, and an injection completion notification function informing the injection completion when the set injection time is completed through the display unit 151. Includes a low flow rate notification function.

The power switch 160 is located on one side of the base body 110, but is for turning on/off the power of the device.

The battery 170 is located on one side of the body portion 110, so that a charging terminal 174 is formed to allow charging.

6 is a view for checking at a glance that the deodorant is injected from the outside through the injection unit 130, and FIG. 7 is a view of spraying the deodorant into the ship air conditioner 10 through the injection device of the present invention It is a drawing showing.

The deodorant used in the present invention is to prepare and use a deodorant utilizing natural microorganisms, and a method of manufacturing a deodorant using natural microorganisms is as follows.

One. For reducing odor Microbial culture stage

To cultivate the microorganism, nutrients Tryptone 5~15 g/L, Peptone 5~10 g/L, Beef extract 1~5 g/L, Yeast extract 1~15 g/L, Sodium chloride 3~7 g/ L, Dipotassium phosphate 0.1~0.5 g/L, Magnesium sulfate 0.03~0.07 g/L are prepared according to the culture capacity to prepare a medium. Preferably Peptone 5~6 g/L, Beef extract 4~5 g/L, Yeast extract 10~12 g/L, Sodium chloride 4~5 g/L, Dipotassium phosphate 0.3~0.4 g/L, Magnesium sulfate 0.05 Prepare the culture process by preparing ~0.06 g/L to remove the medium and proceed with sterilization, and incubation temperature 24~32 ℃, pressure 0.3~0.8 kg/cm2, stirring speed 30~70 rpm, air supply amount 30~120 ml /min, pH is cultured for 24 to 72 hours under the culture conditions of 7.0.

2. Microbial cell recovery step

When the culture is completed through the steps of checking the pH and absorbance of the culture solution, connect the tubular centrifuge and the fermentor to the transfer tube and install the transfer pump. Thereafter, the RPM of the centrifuge is set to 11,000 to 12,500 to operate, and when the set RPM is reached, the lower valve of the fermenter is opened for the transfer of the culture medium to start cell recovery. In addition, the culture filtrate except for the cells is discharged to the outside.

3. Microbial lyophilization step

The recovered cells are subjected to freeze-drying in order to lower the water activity (Aw) of the cells in consideration of storage container properties and microbial activity. The survival of microorganisms is absolutely dependent on the presence of moisture. That is, the usable range of moisture becomes one of the large culture conditions in the growth of microorganisms. The solubility of water is generally expressed in terms of water activity (Aw), and the ratio of water vapor pressure in a solution to water vapor pressure in pure water. In analogy with food, the moisture content of food in microbial growth is not the total moisture content, but the moisture content (= free water) that microorganisms can actually use for growth is a problem. As a result, the effect of suppressing or slowing the growth of microorganisms is obtained through a method of lowering free water.

[Water activity (Aw) = water vapor pressure (P) of samples, products, etc./maximum water vapor pressure of pure water (P ₀₎ ]

It is known that most bacteria require a water activity of 0.91 or more as a minimum growth condition, and proliferation itself is almost impossible at a water activity of 0.50 or less. However, under very low water activity conditions, such as lyophilization, moisture is quickly removed from the microbial cells, so that it can survive for a long time without stopping the activity. In this way, freeze-drying is performed to lower the water activity (Aw) of the microbial sample, thereby lowering the free water contained in the microbial cell, thereby obtaining storage efficiency and an effect of increasing the period of microbial activity.

The recovered cells are powdered through a pre-freezing, shelf temperature control, and freeze-drying process through reduced pressure to utilize them to prepare a deodorant.

4. Microbial deodorant manufacturing step

Microorganisms for odor reduction in ship air conditioners that have been lyophilized are mixed with distilled water to prepare a deodorant. In the manufacturing step of the microorganism deodorant, the microorganism lyophilized powder is mixed with 0.01-5% of sterilized distilled water and 95-99.9% of sterilized water, and preferably the microorganism freeze-dried powder is mixed with 0.01-3% of sterilized distilled water and 97-99.9% of sterilized water.

It is effective to reduce the odor of the air conditioner by injecting the deodorant prepared as above into the injection device of the present invention and spraying it into the air conditioner.

The configuration described in the embodiments and drawings described above are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, and various equivalents and modifications that can replace them It should be understood that there may be examples.

1 deodorant
10 air conditioning
100 injection device
110 Body
111 Deodorant storage unit
111a slot
112 Deodorant Flowmeter
113 buoyancy sensor
114 Supply channels
115 Deodorant Compression Unit
115a 1st air compressor
115a' 1st inlet
115a'' First exhaust
L1 First compressed air line
115b First pressure pump
115b' 1st piston
115b'' first spring
L2 1st inflow line
115c 1st inlet valve
L3 first outflow line
115d 1st drain valve
115e 2nd air compressor
115e' 2nd inlet
115e'' second exhaust
L4 2nd compressed air line
115f Second pressure pump
115f' 1st piston
115f'' first spring
L5 2nd inflow line
115g 2nd inlet valve
L6 second outflow line
115h 2nd drain valve
116 discharge passage
117 Deodorant Mobile Department
117a electric motor
117b deodorant transfer tube
117c bidirectional ball valve
117c' ball valve passage
117d ball valve shaft
120 handle
121 injection switch
130 injection
140 pedestal
150 controls
151 display
152 Injection pressure check
153 Spray status alarm
160 Power Switch
170 batteries
171 charging terminal

Claims (2)

The deodorant is introduced and stored therein, and some of the stored deodorant is compressed by a piston formed therein to move to the injection unit 130;
The handle 120 is located on the upper side of the body portion 110 and the injection switch 121 for turning on/off the spraying operation of the deodorant through the body portion 110;
An injection unit 130 connected to one side of the body unit 110 and formed in a tube shape so that the deodorant compressed from the body unit 110 is sprayed to the outside;
A control unit 150 located on one side of the body portion 110 to control the operation of the body portion 110 for injection of a deodorant;
A power switch 160 positioned on one side of the body part to turn on/off the power of the device;
It is located on one side of the body portion 110, the charging terminal 174 is formed to allow charging the battery 170; includes,
The body portion 110
Deodorant storage unit 111 is formed on the inner side of the body portion 110 and the deodorant is introduced and stored through the inlet 111a formed on one side;
A deodorant flowmeter 112 located inside the deodorant storage unit 111 and measuring the flow rate of the deodorant input to the deodorant storage unit 111;
A buoyancy sensor 113 which is located inside the deodorant storage unit 111 and checks the flow rate of the deodorant stored in the deodorant storage unit 111 to transmit a signal on whether the deodorant is supplied to the deodorant compression unit 115;
It is located between the deodorant storage unit 111 and the deodorant compression unit 115, the supply passage 114 for moving the deodorant from the deodorant storage unit 111 to the deodorant compression unit 115;
The deodorant stored in the deodorant storage unit 111 is moved by the piston operation formed on one side according to the on/off operation of the injection switch 121 of the handle 120, connected to the supply passage 114, and the injection unit ( 130) deodorant compression unit 115 to be supplied to;
A discharge passage 116 connected to the deodorant compression unit 115 to receive deodorant from the deodorant compression unit 115 and to move to the deodorant transfer unit 117;
The deodorant transfer pipe 117b is formed to be connected to the discharge path 116 to move the deodorant received from the discharge path 116, and a two-way ball valve 117c is formed between the deodorant transfer pipe 117b and the two-way Injector for injecting a deodorant utilizing microorganisms, characterized in that it comprises;; deodorant moving unit 117a is formed with an electric motor (117a) for controlling the movement of the ball valve (117c). According to claim 1,
The control unit 150
A display unit that includes a battery remaining amount display function that displays the remaining battery capacity, an injection time setting function that sets the injection time of the deodorant, and a residual injection time confirmation function that checks the remaining injection time for the set injection time through the injection time setting function (151);
It shows the injection pressure, the injection pressure check unit 152 includes a spray pressure control function that allows the user to adjust the pressure in real time the deodorant is sprayed;
Spray including a jet completion notification function to notify the completion of the injection when the set injection time is completed through the display unit 151, a flow rate shortage notification function to receive a shortage of the flow rate signal by the buoyancy sensor 113 to inform the lack of flow rate of the deodorant Status alarm unit 153; injection device for injecting a deodorant utilizing microorganisms, characterized in that it comprises a.

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