KR101349548B1 - A device for killing insects of postharvest fruit against the peach fruit moth by using controlled atmosphere temperature treatment system - Google Patents

Abstract

The present invention applies a controlled atmosphere temperature treatment system technology, which is an environmentally friendly insecticidal technology, to kill peach core moths (Carposina sassakii) inhabiting various fruits including apples, without affecting the fruits. It relates to an environmentally friendly post-harvest insect control device to kill only pests inhabiting the insecticide chamber, the insecticide chamber 10, the gas injection unit 20 for controlling the concentration of carbon dioxide and oxygen in the air composition of the insecticide chamber, It comprises a heater 30 and the cooler 40 for adjusting the temperature of the insecticide chamber, the gas injection unit and the controller 50 for controlling the heater and the cooler, the gas concentration in the pesticide chamber in the controller Is set to 15% of carbon dioxide and 1% of oxygen, and the temperature inside the insecticide chamber is set to 46 ℃ and the signal detected from the internal sensor and the set value Compared to control the operation of the solenoid valve, the cooler and the heater of the gas injection unit, and controls the gas concentration and temperature in the insecticide chamber after processing of the fruit 60 minutes or more under the above conditions.

Description

A device for killing insects of postharvest fruit against the peach fruit moth by using controlled atmosphere temperature treatment system}

The present invention applies a controlled atmosphere temperature treatment system technology, which is an environmentally friendly insecticidal technology, to kill peach core moths (Carposina sassakii) inhabiting various fruits including apples, without affecting the fruits. It relates to an environmentally friendly post-harvest pesticide that allows only pests that live in the genus to be killed.

Controlled Atmosphere Temperature Treatment System, also known as "CATTS", is designed to maximize the insecticidal effect after harvesting by treating the high temperature corresponding to the survival limit of a particular pest under high carbon dioxide and low oxygen environment conditions. Technology (Neven & Mitcham, 1996).

The peach moth (Carposina sassakii) is a primary pest that inflicts fruits inside apples, peaches, and pears. It is distributed mainly in Korea and Japan, and occurs in Korea twice a year. When domestic apples are exported to Taiwan or the United States, peach-rich moths are a major quarantine pest in the country.

Increasing international trade in agricultural products is causing an influx of foreign pests, which will increase economic damage as new pests settle down, causing subsequent crop damage and increasing control costs.

In the United States, these pests reported more than $ 17 billion annually. Naturally, it is required to develop a protection technique and to apply the site to suppress the infestation of pests.

The protection technique is largely divided into chemical and physical treatment methods. The chemical treatment methods include fumigation treatment that penetrates deeper areas of the crop such as methyl bromide and phosphine, and saponification substances or chemical pesticide treatment that remove pests that settle on the surface. Include.

Temperature treatment is a control technique using the survival limit range for the temperature of the pest, environmental control treatment means a temperature treatment combined with a high concentration of carbon dioxide and a low concentration of oxygen.

 Irradiation causes pesticidal effects by disrupting the chemical bonds of the pest's DNA.

Other physical treatments include ozone treatment, microwave treatment, radio frequency treatment, high pressure oxygen treatment and vacuum treatment.

Environmental control heat treatment, also known as CATTS, is one of the physical treatment technologies that maximizes the protection effect while treating the high temperature corresponding to the survival limit of a particular pest under high carbon dioxide and low oxygen environment conditions. After harvesting, various fruit pests have been verified by insecticide technology and proposed as an alternative method of chemical insecticide treatment. Methyl bromide, a conventional chemical insecticide method, is expected to be gradually banned as an ozone depleting substance. Since it is not suitable for use in fruit, there is no weakness and development of environment-friendly insecticide is required.

The present invention has been made to solve the above problems, an object of the present invention is to use only environmentally friendly heat treatment technology to kill the peach core moth inhabiting the fruit without affecting the fruit, such as apples, peaches, pears To provide an environmentally friendly post-harvest pesticide.

In order to achieve the above object, the present invention applies a controlled atmosphere temperature treatment system technology, which is an environmentally friendly insecticide technology, to kill only pests inhabiting the fruit without affecting the fruit. ; A gas injection unit for controlling the concentration of carbon dioxide and oxygen in the air composition of the insecticide chamber; A heater and a cooler for controlling the temperature of the insecticide chamber; And a controller for controlling the gas injection unit, the heater, and the cooler. Provides a pesticide after harvest of peach hearted moth by environmental control heat treatment technology comprising a.

In the present invention, the insecticide chamber is provided with a multi-stage shelf for placing the fruit (box containing the fruit) as a pesticide, a circulation fan for the convection of the internal air, and for detecting the temperature and gas concentration inside the insecticide chamber An internal sensor and a discharge port for discharging air inside the insecticide chamber to the outside are provided, and the discharge port is provided with a sensor for detecting the concentration of the exhaust gas, that is, the air composition.

In the present invention, the gas injection unit is three kinds of gas cylinders filled with carbon dioxide, nitrogen gas and air, respectively, the solenoid valves installed at the outlets of the three gas cylinders, nitrogen and carbon dioxide released through each solenoid valve and It comprises a manifold in which air is mixed and injected into the pesticide chamber.

In the present invention, the control unit sets the gas concentration inside the pesticide chamber to 15% carbon dioxide and oxygen 1%, and sets the temperature inside the insecticide chamber to 46 ° C. to compare the signal detected by the internal sensor with a preset value. It controls the operation of solenoid valves, coolers and heaters in the injecting section, and processes the gas concentration and temperature inside the insecticide chamber for 60 minutes under the conditions after the introduction of fruit to survive specific pests under high carbon dioxide and low oxygen environments. By processing the high temperature limit, it is possible to kill only pests that live in the fruit without affecting the fruit.

According to the treatment apparatus of the present invention, after the internal temperature of the insecticide chamber reaches 46 ° C, the insecticidal effect of the peach hearted moth, which injects the fruit into the fruit according to the exposure time, increases as the treatment time increases. It has been found that it has a pesticidal effect, according to the present invention has a useful effect capable of economical and environmentally friendly pesticides compared to other physical control techniques.

1 is an overall configuration diagram of the insecticide after harvesting peach core moth by the environmental control heat treatment technology according to the present invention,
2 is a side view of the insecticide chamber,
3 is a control flow chart of the insecticide according to the present invention,
Figure 4 is a graph showing the control effect according to the exposure time in the present invention.

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

Figure 1 shows the overall configuration of the insecticide after harvesting peach core moth by the environmental control heat treatment technology according to the present invention, Figure 2 is a side view of the insecticide chamber, Figure 3 is controlled in the insecticide device according to the present invention It shows the flow.

As shown in Figures 1 to 3 the present invention is a pesticide chamber (10); A gas injection unit 20 for controlling the concentration of carbon dioxide and oxygen in the air composition of the insecticide chamber 10; A heater 30 and a cooler 40 for controlling the temperature of the insecticide chamber 10; And a controller 50 for controlling the gas injection unit 20, the heater 30, and the cooler 40. .

In the present invention, the insecticidal chamber 10 is provided with a multi-stage shelf 11 for placing fruit as a pesticide, and a circulation fan 12 for convection of air in the insecticidal chamber 10 is installed at left and right sides. The internal sensor 13 for detecting the temperature and gas concentration inside the insecticide chamber 10 is provided.

In addition, the upper portion of the insecticide chamber 10 is provided with a discharge port 14 for discharging the air inside the insecticide chamber 10 to the outside, the exhaust port 14 to detect the concentration of the exhaust gas, that is, the air composition External sensor 15 is provided for.

In addition, the heater 30 is disposed on the side surface of the insecticide chamber 10, and a cooler 40 made of a Peltier element is installed on the insecticide chamber 10 to control the air temperature inside the insecticide chamber 10. It is adjustable.

The cooler 40 is also applicable to the method using a common refrigerant in addition to the Peltier element.

In the present invention, the gas injection unit 20 is three kinds of gas cylinders 21, 22 and 23 filled with carbon dioxide, nitrogen gas and air, respectively, and the outlet sides of the gas cylinders 21, 22 and 23, respectively. Installed solenoid valves (24, 25, 26) and the manifold (27) which is injected into the insecticide chamber (10) by mixing nitrogen and carbon dioxide and air discharged through each solenoid valve (24, 25, 26) The solenoid valves 24, 25, and 26 are automatically opened and closed by an electrical signal of the controller 50.

On the other hand, the pipe between the gas cylinder (21, 22, 23) and the solenoid valve (24, 25, 26) and between the solenoid valve (24, 25, 26) and the manifold (27) to prevent the back flow of gas Check valve is installed.

In the present invention, the controller 50 sets the gas concentration in the insecticide chamber 10 to 15% of carbon dioxide and 1% of oxygen, and sets the temperature of the insecticide chamber 10 to 46 ° C. in the internal sensor 13. The operation of the solenoid valves 21, 22, 23, the heater 30, and the cooler 40 of the gas injection unit 20 is controlled by comparing the detected signal with a value set by the controller 50. The control process at 50 is shown in FIG.

Hereinafter will be described a specific embodiment of the process for killing the harvested apples using the insecticide of the present invention.

[Example 1]

As shown in FIG. 3, in the present invention, when the start button is pressed during the operation of the controller 50, the control of oxygen concentration (S1) is performed first, and then the control of carbon dioxide concentration (S2) is performed. Then, temperature control (S3) is performed, in the oxygen concentration control step (S1) after the introduction of apples by operating the fan of the outlet 14 to decompress the interior of the insecticide chamber 10 to lower the oxygen concentration and then nitrogen gas is introduced. By lowering the oxygen concentration, when the concentration of oxygen is less than 5%, nitrogen and carbon dioxide are added together so that each concentration automatically reaches 1% of oxygen and 15% of carbon dioxide (S2).

Next, the heater 30 is driven for 1 hour to reach the target temperature (65 ° C.) from the room temperature (usually 25 ° C.) (S3). At this time, the temperature inside the apple was 35 ℃, to maintain the target temperature (46 ℃) for 1 hour to increase the temperature inside the apple to 44 ℃ (S4).

In this embodiment, the target temperature (46 ° C .; internal temperature of the insecticide chamber) and the fruit internal temperature (44 ° C.) are adjusted for 20 minutes, 40 minutes, and 45 while maintaining a constant oxygen concentration of 1% and a carbon dioxide concentration of 15%. Treatment was performed for minutes, 50 minutes and 60 minutes to confirm the respective control effects.

After the internal temperature of the insecticidal chamber 10 reaches 46 ° C., the results of analyzing the control effect of the peach hearted moth that apply the inside of the apple according to the exposure time are shown in FIG. 4.

As shown in FIG. 4, the insecticidal effect of the peach hearted moth in the present embodiment showed a tendency to increase with increasing treatment time, and in particular, it was confirmed that the insecticidal effect of 100% was obtained after 60 minutes of treatment.

This pesticidal effect tended to increase as the oxygen pollution was prevented through several previous studies. In other words, when the treatment of carbon dioxide to suppress the inflow of oxygen by supplying nitrogen into the insecticide chamber, it was found that the insecticidal effect is higher than simply treating carbon dioxide.

On the other hand, as a result of monitoring the temperature of the insecticide chamber and the inside of the fruit processed in the insecticide chamber, the temperature exposed to the peach core moth is experiencing the temperature inside the fruit processed in the insecticide chamber rather than the temperature of the insecticide chamber. Results The process temperature change starting at 25 ° C increased the temperature inside the insecticide chamber to 46 ° C after 60 minutes, but the temperature inside the fruit exceeded 40 ° C after 90 minutes and ultimately reached 43.5 ° C after 120 minutes. .

As a result of investigating the browning rate during the storage period in the cold storage for the apples treated by the present embodiment and the untreated apples as a control, the untreated apples did not show internal browning during the storage period of 120 days, the insecticidal of the present invention Apples treated for 60 minutes by the device did not develop browning until 120 days. However, in the case of apples treated for 90 minutes in the insecticide of the present invention it was confirmed that the occurrence of browning inside the apple increases with the storage period.

In addition, as a result of analyzing the physical and chemical changes of the apples subjected to the insecticidal treatment according to the present embodiment, hardness, sugar, and acidity were not different from those of the control apples, and as a result of measuring the ethylene incidence, Although it increased from about 1.5 times to 16 times after 7 days of cold storage, in the present invention, it was confirmed that the ethylene generation rate decreased as the storage period passed 14 days, and the respiratory volume of untreated apples decreased from 1 day to 30 days. After 60 days, the increase and decrease was repeated, and the present invention confirmed that the respiratory volume was increased and decreased regardless of the storage period.

[Example 2]

After the treatment of peaches (whiteness) under the same conditions as in Example 1, the internal browning rate during the storage period in the cold storage (1 ℃) was investigated. As a result of peeling the seeds of the peach and cutting it to the end, the internal browning rate was confirmed. As a result, the internal browning rate of the untreated peach increased after 7 days. Peaches treated by the insecticidal apparatus of the present invention were stored for 7 days when treated up to 60 minutes, and stored for more than 7 days after treatment for 60 minutes or more showed that the occurrence of internal browning increases with storage period.

In addition, as a result of analyzing the physical and chemical changes of the peach treated with pesticides according to the present embodiment, hardness, sugar, and acidity did not differ from the untreated peach, which was a control. There was a slight difference, and the increase in treatment time and longer storage period tended to decrease the ethylene generation rate of peaches.

In addition, as a result of measuring the respiration rate of the peach according to the treatment time and the storage period according to the present invention, it was confirmed that the increase and decrease until 7 days storage starting from 3 days cold storage in the untreated and treated section.

As confirmed in Examples 1 and 2 described above, apples and peaches, which have passed through the insecticidal apparatus of the present invention, have little effect on the physicochemical properties of the fruit, and it is proved that only pests inhabiting the fruit can be killed. .

As described above, the present invention controls the gas concentration, that is, the oxygen concentration and the carbon dioxide concentration in the insecticide chamber using an environmentally controlled heat treatment technology, which is an environmentally friendly insecticide method, and the temperature in the insecticide chamber is maintained at 46 ° C. for at least 1 hour. By injecting 100% of the peach hearted moths inside the fruit without affecting the organization and quality of the fruit at all, it is possible to pass the quarantine that has been a problem for the export of the fruit. It is possible to increase.

10: insecticide chamber 11: shelf
12: circulation fan 13: internal sensor
14 outlet 15: external sensor
20: gas injection unit 21: gas cylinder (carbon dioxide)
22: gas cylinder (oxygen) 23: gas cylinder (air)
24, 25, 26: solenoid valve 27: manifold
30: heater 40: cooler
50:

Claims (3)

Environmental control heat treatment to control the gas inlet, heater and cooler to control the concentration of carbon dioxide and oxygen in the air composition inside the insecticide chamber and to control the temperature inside the insecticide chamber while the fruit is placed inside the insecticide chamber As a insecticide after harvest of peach hearted moths by technology;
The insecticide chamber 10 is provided with shelves 11 for placing fruit in multiple stages, the internal sensor 13 for detecting the temperature and gas concentration inside the insecticide chamber 10, and the insecticide chamber 10 inside A discharge port 14 for discharging the air to the outside is provided, the discharge port is provided with an external sensor 15 for detecting the air composition of the exhaust gas;
The gas inlet 20 is three kinds of gas cylinders 21, 22, and 23 filled with carbon dioxide, nitrogen gas, and air, respectively, and solenoids installed at outlet sides of the gas cylinders 21, 22, and 23, respectively. Nitrogen, carbon dioxide, and air discharged through the valves 24, 25, 26 and the respective solenoid valves 24, 25, 26 are mixed and injected into the insecticide chamber, and the gas cylinders 21, 22. A check valve is provided between the 23 and the solenoid valves 24, 25 and 26 and between the solenoid valves 24 and 25 and 26 and the manifold 27 to prevent backflow of gas;
The controller 50 sets the gas concentration in the insecticide chamber 10 to 15% of carbon dioxide and 1% of oxygen, and sets the temperature of the insecticide chamber 10 to 46 ° C. to be detected by the internal sensor 13. Compare the signal and the set value to control the driving of the solenoid valves 24, 25, 26, the heater 30, and the cooler 40 of the gas injection unit 20, and after the fruit is injected, the interior of the insecticide chamber 10. Insecticide after harvesting peach core moth by environmental control heat treatment technology, characterized in that the gas concentration and temperature of 60 minutes under the above conditions is set to process. The method according to claim 1,
The insecticide after harvesting the peach core moth by the environmental control heat treatment technology, characterized in that the circulation fan 12 for the convection of the internal air is installed inside the insecticide chamber 10 for uniformity of temperature and gas composition . The method according to claim 2,
The circulating fan 12 is a pesticide after harvesting by environmental control heat treatment technology, characterized in that the plurality is installed so as to face up and down on the left and right sides inside the insecticide chamber (10).

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