KR102625155B1 - Device for measuring and protecting odor in animal house - Google Patents

Abstract

The present invention relates to a livestock house odor measurement and blocking device that measures the concentration and change in odor generated within a livestock house and blocks the odor generated in the livestock house.
In other words, the present invention continuously (real-time) measures ammonia, which is an odorous substance generated in a livestock house, and accurately measures the current concentration of odor in the livestock house using a simple optical sensor for detecting odor. The aim is to provide a livestock odor measuring and blocking device that can block odor from escaping to the outside by operating the air curtain mounted on the ventilation window and entrance of the livestock house if the measured odor concentration is higher than the standard value.

Description

Device for measuring and protecting odor in animal house}

The present invention relates to a livestock house odor measuring and blocking device, and more specifically, to a livestock house odor measuring and blocking device that measures the concentration and change in odor generated within the livestock house and blocks the odor generated in the livestock house. .

In general, if the treatment of livestock excrement or sewage is not performed in a timely manner in a livestock barn, which refers to a place where livestock are raised, a foul odor is generated and spread by gases such as hydrogen sulfide, ammonia, acetaldehyde, etc. generated from the excrement.

If the odor generated from these livestock houses is inhaled through the respiratory tract of livestock for a long period of time, it not only causes the death of livestock, but also spreads to nearby farms and private homes, becoming a cause of civil complaints.

To elaborate, the manure that livestock excretes out of the body after consuming feed is a gaseous substance (e.g. ammonia, which is composed of nitrogen (N) and hydrogen (H)), which is the main cause of the unpleasant odor that irritates the human nose and causes discomfort and disgust. compounds, etc.), and odor complaints are continuously increasing due to negligence in odor management. In order to reduce odor and resolve and prevent related complaints, the “Livestock Odor Monitoring System” using ICT technology has been implemented since August 2018. ” is in progress.

Therefore, a process to remove odor by deodorizing odor gas before a certain level of odor gas is generated in the livestock house is essential.

To this end, it is most important to accurately measure how much bad odor is currently being generated in the livestock house. This is because if the bad smell is above a certain level, an odor deodorizing device must be operated, but even if the bad smell is below a certain level, the bad smell must be activated. This is because power waste may occur as the deodorizing device is operated.

Republic of Korea Patent Publication No. 10-2019-0088117 (2019.07.26)

The present invention was developed to solve the above-described conventional problems. The present invention continuously (real-time) measures ammonia, which is an odorous substance generated within a livestock house, using an optical sensor for detecting odor with a simple structure. It is possible to accurately measure how much odor concentration is currently being generated, and if the measured odor concentration is above the standard value, the air curtain installed on the ventilation window and entrance of the livestock house is activated to block the odor from escaping to the outside. The purpose is to provide measuring and blocking devices.

In order to achieve the above object, the present invention includes: an optical sensor for detecting odor consisting of a laser light source mounted on one wall of the livestock house and a light reception and detection unit mounted on the other wall of the livestock house; a control unit that controls the number and amount of laser beam irradiations to the light source and determines an odor concentration based on the detection signal of the light reception and detection unit; and an air curtain mounted on the ventilation window and entrance of the livestock house and driven by a control signal from the control unit when the odor concentration determined by the control unit is higher than a standard value; Provided is a livestock odor measuring and blocking device comprising:

The livestock odor measuring and blocking device of the present invention includes: a sample tube connected between the light source and the light receiving and detecting unit, and having a gas inlet and a gas outlet formed to guide the irradiation direction of the laser beam and simultaneously introduce and discharge odor gas in the livestock barn; A suction blower mounted on the gas inlet of the sample tube to suck gas into the sample tube; and an exhaust blower mounted on the gas outlet of the sample tube to discharge gas to the outside of the sample tube. It is characterized in that it further includes.

The livestock odor measuring and blocking device of the present invention further includes a first camera that monitors changes in the number of livestock in the livestock barn and transmits the information to the control unit, and a second camera that monitors changes in excrement excreted by livestock in the livestock barn and transmits the data to the control unit. It is characterized in that the control unit is configured to determine whether to operate the air curtain based on the livestock number change signal transmitted from the first camera and the excrement change signal transmitted from the second camera.

By solving the above problems, the present invention provides the following effects.

First, by providing an optical sensor for detecting odor with a simple structure consisting of a light source and a light receiving and detecting unit, and mounting the light source and the receiving and detecting unit at opposite positions within the livestock house, ammonia, which is an odorous substance generated within the livestock house, is continuously ( By enabling measurement in real time, it is possible to simply measure how much odor concentration is currently being generated within the livestock house.

Second, if the odor concentration is above the standard value based on the detection signal detected by the light reception and detection unit of the optical sensor for odor detection, the air curtain mounted on the ventilation window and entrance of the livestock house is activated to block the odor from escaping to the outside. It can resolve odor complaints caused by odor spreading to nearby private homes.

Third, in addition to the optical sensor for detecting odor, by installing a first camera that monitors changes in the number of livestock in the barn and a second camera that monitors the change in the amount of excrement excreted by livestock, the number of livestock in the barn is greater than the standard number or the amount of excrement (on the bottom of the barn) is installed. If the excrement accumulation area compared to the area is more than the standard amount, the air curtains installed on the ventilation window and entrance of the livestock house are activated to block the odor from escaping to the outside, thereby preemptively responding to odor complaints due to the odor spreading to surrounding private houses. It can be resolved.

1 is a configuration diagram showing a device for measuring and blocking livestock odor according to an embodiment of the present invention;
Figure 2 is a configuration diagram showing a device for measuring and blocking odor in a livestock house according to another embodiment of the present invention.

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

The attached FIG. 1 is a configuration diagram showing a device for measuring and blocking odor in a livestock house according to an embodiment of the present invention, and FIG. 2 is a diagram showing a device for measuring and blocking odor in a livestock facility according to another embodiment of the present invention.

As shown in Figures 1 and 2, it is an optical sensor for detecting malodor for detecting malodor generated within the livestock house, and a laser light source 110 is mounted on one wall of the livestock house 100, and the livestock house 100 A light reception and detection unit 120 is mounted on the other wall of the interior.

Compared to expensive optical sensors, the optical sensor for detecting odor has a simple structure consisting of only a light source 110 and a light reception and detection unit 120, and only the light source 110 and the light reception and detection unit 120 are located at opposite positions in the livestock house. It is equipped to continuously (real-time) measure ammonia, an odorous substance generated within a livestock farm, at a low cost.

Accordingly, when a laser beam is irradiated from the light source 110 toward the light receiving and detecting unit 120, a portion of the laser beam touches the odorous gas (e.g., ammonia, etc.) generated within the livestock house 100, causing odorous gas particles to increase in amount of light. As absorbed, the amount of light absorbed by the gas particles becomes undetectable.

At this time, the light reception signal detected by the light reception and detection unit 120 is transmitted to the control unit 200.

The control unit 200 is configured to control the number and amount of laser beam irradiations to the light source 110 and determine the odor concentration based on the detection signal of the light reception and detection unit 120.

For example, the control unit 200 determines the odor concentration according to the amount of light received from the laser beam based on the detection signal from the light reception and detection unit 120.

Therefore, by enabling continuous (real-time) measurement of ammonia, which is an odorous substance generated within the livestock house 100, using only an optical sensor for detecting odor with a simple structure consisting of the light source 110 and the light receiving and detecting unit 120, It is possible to easily measure the current concentration of odor in a livestock farm.

On the other hand, the odor gas generated within the livestock house 100 may be widely spread throughout the internal space of the livestock house or may be concentrated in a local space within the internal space of the livestock house, so the current odor gas concentration within the livestock house can be detected more efficiently and intensively. It is desirable to be able to do so.

For this purpose, a sample tube 150 having a gas inlet and a gas outlet is connected between the light source 110 and the light reception and detection unit 120 to guide the irradiation direction of the laser beam and simultaneously introduce and discharge odorous gas in the livestock house. .

In addition, a suction blower 151 is installed at the gas inlet of the sample tube 150 to suck gas into the sample tube, and an exhaust blower 152 is installed at the gas outlet of the sample tube 150 to discharge gas to the outside of the sample tube. ) is installed.

Accordingly, as the suction blower 151 and the discharge blower 152 are driven, the odorous gas in the livestock house may circulate and flow intensively into the sample tube 150.

Therefore, the laser beam irradiated from the light source 110 can be easily irradiated toward the light receiving and detecting unit 120 along the sample tube 150, and a portion of the laser beam irradiated into the sample tube 150 is included in the sample tube ( As it touches the odorous gas in the sample tube 150 and changes its irradiation angle, it is not detected by the light receiving and detecting unit 120, while another part of the laser beam passes through the odorous gas in the sample tube 150 and is detected by the light receiving and detecting unit 120. It can be easily detected, and ultimately, the odorous gas generated within the livestock house 100 can be detected more efficiently and intensively.

Likewise, the signal detected by the light reception and detection unit 120 through the odorous gas in the sample tube 150 is transmitted to the control unit 200, and the control unit 200 transmits the laser beam based on the detection signal of the light reception and detection unit 120. The odor concentration is determined depending on the amount of light received.

At this time, if the odor concentration determined by the control unit 200 is greater than or equal to the standard value, the control unit 200 controls the air curtain 160 to be driven.

That is, the air curtain 160 mounted on the ventilation window and entrance of the livestock house 100 is driven by a control signal from the control unit 200, thereby controlling the operation of the air curtain 160 on the ventilation window and entrance of the livestock house 100. An air curtain can be formed, and this air curtain can easily block bad odors from escaping to the outside of the livestock house, ultimately resolving complaints about bad smells caused by the bad smell spreading to surrounding private houses.

Meanwhile, a first camera 130 monitors changes in the number of livestock in the livestock shed 100 and transmits them to the control unit 200, and a second camera 130 monitors changes in feces excreted by livestock in the livestock sheds and transmits them to the control unit 200. Two more cameras 140 may be installed.

If the optical sensor for detecting odor, which consists of the laser light source 110 and the light receiving and detecting unit 120, fails, the control unit 200 receives the livestock number change signal transmitted from the first camera 130 and the second camera 130. It is possible to determine whether to operate the air curtain 160 based on the excrement change signal transmitted from the camera 140.

For example, if the optical sensor for detecting odor consisting of the laser light source 110 and the light receiving and detecting unit 120 breaks down, the control unit 200 detects the livestock based on the livestock number change signal transmitted from the first camera 130. If the number of livestock producing odorous gas is greater than the standard value, or if the amount of livestock excrement in the barn (excrement accumulation area compared to the barn floor area) is greater than the standard amount based on the excrement change signal transmitted from the second camera 140, the air curtain 160 is activated. Controls the operation.

Therefore, even if the optical sensor for detecting odor consisting of the laser light source 110 and the light receiving and detecting unit 120 is broken, the livestock house 100 is detected based on the shooting signals of the first camera 130 and the second camera 140. ) by operating the air curtain 160 mounted on the ventilation window and entrance to block odor from escaping to the outside, it is possible to preemptively resolve odor complaints due to odor spreading to surrounding private houses.

Meanwhile, a contamination-resistant coating layer made of an anti-fouling coating composition may be applied to the air curtain 160, the first camera 130, and the second camera 140 to improve contamination resistance.

The anti-fouling coating composition contains sodium sulfate and alkyl ethoxylate ether in a molar ratio of 1:0.01 to 1:2, and the total content of sodium sulfate and alkyl ethoxylate ether is 1 to 12% by weight based on the total aqueous solution. am.

The molar ratio of the sodium sulfate and the alkyl ethoxylate ether is preferably 1:0.01 to 1:2. If the molar ratio is outside the above range, the air curtain 160, the first camera 130, and the second camera 140 are used. There is a problem that the coating film is removed due to reduced applicability or increased moisture adsorption on the surface after application.

The sodium sulfate and alkyl ethoxylate ether are preferably contained in an amount of 1 to 12% by weight in the total composition aqueous solution. If the amount is less than 1% by weight, the applicability of the air curtain 160, the first camera 130, and the second camera 140 is poor. There is a problem of deterioration, and if it exceeds 12% by weight, crystal precipitation is likely to occur due to an increase in the thickness of the coating film.

Meanwhile, it is preferable to apply the anti-fouling composition to the air curtain 160, the first camera 130, and the second camera 140 by spraying. In addition, the final coating film thickness of the air curtain 160, the first camera 130, and the second camera 140 is preferably 900 to 2300 Å. If the thickness of the coating film is less than 900 Å, there is a problem of deterioration in the case of high temperature heat treatment, and if it exceeds 2300 Å, there is a disadvantage that crystal precipitation on the coating surface is likely to occur.

Additionally, this stain-resistant coating composition can be prepared by adding 0.1 mole of sodium sulfate and 0.05 mole of alkyl ethoxylate ether to 1000 ml of distilled water and then stirring.

The reason for limiting the ratio of the components and the thickness of the coating film to the above values is that the present inventor analyzed the test results after repeated failures and found that the ratio showed the optimal anti-contamination application effect.

In addition, the circumference of the sample tube 150 may be coated with an environmental fragrance material mixed with functional oils that help sterilize and relieve stress in animals.

The mixing ratio of the fragrance material and the functional oil is 95 to 97% by weight of the fragrance material and 3 to 5% by weight of the functional oil, and the functional oil is 45% by weight of thyme oil and 55% by weight of tarragon oil. It is made up of weight percent.

Here, it is preferable that the functional oil is mixed in an amount of 3 to 5% by weight based on the fragrance material. If the mixing ratio of the functional oil is less than 3% by weight, the effect is minimal, and if the mixing ratio of the functional oil exceeds 3 to 5% by weight, the effect is not significantly improved and the economic feasibility is low. Thyme oil contains ingredients with strong sterilizing power and has antiseptic effects, while tarragon oil is effective in relieving stress. Therefore, by coating the optical sensor 10 for detecting malodor with a fragrance material mixed with such functional oils, effects such as sterilizing the area around the sample tube 150 and relieving stress in animals can be obtained.

The reason for limiting the components and limiting the mixing ratio for environmental fragrance materials and functional oils is that the present inventor analyzed the test results after repeated failures and found that the optimal composition and numerical ratio was determined. showed the effect.

Additionally, a sound-absorbing layer can be attached to the inside of the external case of the control unit 200.

Natural fiber non-woven fabric may be used as the sound-absorbing layer.

The thickness of the sound-absorbing layer is preferably 0.5 to 15 mm. If the thickness of the sound-absorbing layer is less than 0.5 mm, sufficient sound-absorbing effect is not obtained, and if it exceeds 15 mm, sufficient space inside the external case of the control unit 200 is not secured, which is a disadvantage in that the temperature of the control unit 200 can be increased. Not desirable.

The unit weight of the sound-absorbing layer is preferably 12 to 600 g/m ² . If it is less than 12 g/m ² , sufficient sound absorption effect is not obtained, and if it is more than 600 g/m ^{2 ,} it is not preferable because the lightness of the control unit 200 cannot be secured.

The fineness of the fibers constituting the sound-absorbing layer is preferably in the range of 0.5 to 25 decitex. Below 0.5 decitex, it is undesirable because it is difficult to absorb low-frequency noise and the cushioning properties deteriorate, and if it exceeds 25 decitex, it is undesirable because it is difficult to absorb high-frequency noise.

The tensile strength of the nonwoven fabric of the sound-absorbing layer is 10Kgf/cm2, and the noise reduction coefficient (NRC) is 0,680.

Since the sound-absorbing layer is attached to the inside of the external case of the control unit 20, the noise of the control unit 20 can be reduced.

The reason for limiting the components such as non-woven fabric, thickness, weight, and fineness that make up the sound-absorbing layer and limiting the numerical value of the component ratio is that the present inventor analyzed the test results after repeated failures and found that the components and The optimal sound absorption effect was shown at a limited numerical ratio.

In addition, a heat dissipation coating is applied to the surface of the external case of the control unit 200 to allow the heat emitted from the control unit 200 to be smoothly discharged to the outside, thereby preventing the control unit 200 from being excessively heated and dissipating heat effectively. there is.

This heat dissipation coating composition contains 12% by weight of butyl cellosolve, 43% by weight of methyltrimethoxysilane, 8% by weight of chromium oxide, 11% by weight of graphite, 7% by weight of silicon nitride, 5% by weight of sodium hydroxide (NaOH), and titanium oxide. It consists of 4% by weight, 3% by weight of fumed silica, and 7% by weight of 3-mercaptopropyl trimethoxysilane.

Butyl cellosolve plays a role in protecting the heat dissipation coating layer, methyltrimethoxysilane acts as a binder resin, chromium oxide acts as wear resistance, graphite has excellent thermal conductivity and electrical properties, and silicon nitride improves strength and It prevents cracking, sodium hydroxide acts as a dispersant, titanium oxide serves for weather resistance, fumed silica acts as an anti-settling agent, and 3-mercaptopropyl trimethoxysilane acts as an adhesion enhancer.

It is preferable that the heat dissipation thickness is 8 to 1500㎛.

The reason for limiting the constituent materials and components and limiting the mixing ratio as described above is that the present inventor analyzed the test results after repeated failures and found that the optimal effect was achieved with the above-mentioned constituents and numerical ratio. indicated.

A shock absorbing unit may be attached and installed on the bottom of the computer control unit 200.

The impact cushioning part may be made of a rubber material, and the raw material content ratio of this shock absorbing part is 68% by weight of rubber, 9% by weight of trimethylthiourea, 8% by weight of aromatic oil, 9% by weight of carbon black, and 3C (N-PHENYL-N Mix 6% by weight of '-ISOPROPYL- P-PHENYLENEDIAMINE).

Trimethylthiourea is added to accelerate vulcanization, aromatic oil is added to act as a softener, carbon black is added to increase or improve wear resistance and thermal conductivity, and 3C (N-PHENYL-N'- ISOPROPYL-P-PHENYLENEDIAMINE) is added as an antioxidant,

Therefore, the present invention improves durability by increasing the elasticity, toughness, and rigidity of the impact cushioning portion, and thus increases the lifespan of the shock cushioning portion.

The tensile strength of the rubber material is 150Kg/㎠ and the elongation is 620%.

The reason for limiting the rubber material and components and limiting the mixing ratio values, etc. is that the present inventor analyzed the test results after repeated failures and found that the optimal effect was achieved with the above-mentioned components and numerical ratios. indicated.

100: Barn
110: light source
120: light receiving detection unit
130: first camera
140: second camera
150: Sample tube
151: Suction blower
152: exhaust blower
160: Air curtain
200: control unit

Claims (3)

An optical sensor for detecting odor consisting of a laser light source 110 mounted on one wall of the livestock house 100 and a light reception and detection unit 120 mounted on the other wall of the livestock house 100;
A control unit 200 that controls the number and amount of laser beam irradiations to the light source 110 and determines the odor concentration based on the detection signal of the light reception and detection unit 120; and
It is mounted on the ventilation window and entrance of the livestock house 100 and is configured to include an air curtain 160 that is driven by a control signal from the control unit 200 when the odor concentration determined by the control unit 200 is above the standard value;
A sample tube 150 connected between the light source 110 and the light reception and detection unit 120, and having a gas inlet and a gas outlet to guide the irradiation direction of the laser beam and simultaneously introduce and discharge odorous gas in the livestock house; A suction blower 151 mounted on the gas inlet of the sample tube 150 to suck gas into the sample tube; and an exhaust blower 152 mounted on the gas outlet of the sample tube 150 to discharge gas to the outside of the sample tube.
A first camera 130 that monitors changes in the number of livestock in the livestock shed 100 and transmits the data to the control unit 200, and a second camera that monitors changes in excrement from livestock in the livestock shed and transmits the data to the control unit 200. It further includes (140), and the control unit 200 controls the air curtain (160) based on the livestock population change signal transmitted from the first camera 130 and the excrement change signal transmitted from the second camera 140. ) is configured to determine whether to drive;
A sound-absorbing layer is attached to the inside of the external case of the control unit 200, and the sound-absorbing layer is made of natural fiber non-woven fabric, the thickness of the sound-absorbing layer is 0.5 to 15 mm, and the unit weight of the sound-absorbing layer is 12 to 600 g/m. ² , the fineness of the fibers constituting the sound-absorbing layer is in the range of 0.5 to 25 decitex, the tensile strength of the nonwoven fabric of the sound-absorbing layer is 10Kgf/cm2, and the noise reduction coefficient (NRC) is 0.680;
A heat dissipation coating is applied to the surface of the external case of the control unit 200, and the heat dissipation coating agent includes 12% by weight of butyl cellosolve, 43% by weight of methyltrimethoxysilane, 8% by weight of chromium oxide, 11% by weight of graphite, and silicon nitride. It consists of 7% by weight, sodium hydroxide (NaOH) 5% by weight, titanium oxide 4% by weight, fumed silica 3% by weight, and 3-mercaptopropyl trimethoxysilane 7% by weight;
A shock absorbing part is attached to the bottom of the computer control unit 200, and the raw material content of the shock absorbing part is 68% by weight of rubber, 9% by weight of trimethylthiourea, 8% by weight of aromatic oil, 9% by weight of carbon black, and 3C. It is made by mixing 6% by weight of (N-PHENYL-N'-ISOPROPYL- P-PHENYLENEDIAMINE);
The circumference of the sample tube 150 is coated with an environmental fragrance material mixed with functional oil, and the mixing ratio of the fragrance material and the functional oil is 95 to 97% by weight of the fragrance material and 3 to 5% by weight of the functional oil. A livestock odor measuring and blocking device that is mixed, and the functional oil is comprised of 45% by weight of thyme oil and 55% by weight of tarragon oil. delete delete

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