KR101284473B1 - Low oxygen disinfestation devices for cultural heritage conservation - Google Patents

Abstract

PURPOSE: A cultural properties preservation low oxygen concentration insecticide apparatus is provided to rapidly charge the insecticide gas to a chamber by the pressure of the chamber, by an insecticide gas supplying unit supplying the insecticide gas into the chamber after making a gas removal unit making the chamber into vacuum. CONSTITUTION: A cultural properties preservation low oxygen concentration insecticide apparatus is comprised of a chamber (10), a locker, a gas removal unit, an insecticide gas supplying unit, an exhausting unit, and a controller. The inside of chamber is sealed in the hermetic status. A rotary shaft is prepared and a door (12) which opens and closes by rotating around the center of the rotary shaft is prepared. The cultural properties are built in through the door. The locker locks the door of chamber. The gas removal unit removes the charged gas inside the chamber. The insecticide gas supplying unit supplies the insecticide gas which is necessary to insecticide the cultural properties to the chamber. The exhausting unit exhausts the insecticide gas supplied to the chamber or the internal air of the chamber to the outside of the chamber. The controller controls the operation of the exhausting unit, the gas removal unit, and the insecticide gas supplying unit.

Description

{LOW OXYGEN DISINFECTION DEVICES FOR CULTURAL HERITAGE CONSERVATION}

The present invention relates to a hypoxic insecticidal apparatus for preserving cultural heritage, and more particularly, to a hypoxic insecticidal apparatus for preserving cultural heritage that exposes cultural properties requiring preservation to a hypoxic environment to insect pests of cultural properties.

In general, cultural assets that can be corrupted, such as high-rise buildings and old books, are damaged or corrupted by insects or harmful bacteria, so they should be periodically insecticidal. In particular, cultural properties of organic materials, such as wood, paper or fiber, are damaged or corrupted by threats from the invasion of organisms (insects, fungi, etc.) as a potential source of damage. One of the ways to effectively eliminate these harmful organisms is to control them, such as insecticides and sterilization.

However, insecticides and fungicides used in the control can cause undesirable side effects (modification of form or material) in organic materials, and they have also been a risk to the human body and the environment. In particular, methyl bromide, which is widely used as a fumigant, is the ozone depletion material of the earth. The deadline for final disposal was determined in the Montreal Protocol in 1997, the developed countries were banned in 2005, and the developing countries including Korea were scheduled to be fully exhausted in 2015. As a result, studies on the use of high temperature and low temperature, radiation, hypoxic concentration using nitrogen or argon gas, and insecticidal method using carbon dioxide as an alternative to methyl bromide have been increased. Of these, hypoxic insecticides, carbon dioxide insecticides and low temperature methods using nitrogen or argon are widely used in the world as insecticides for preservation of cultural properties.

Here, the aforementioned hypoxic concentration insecticidal method utilizes such a death mechanism of insects. To explain this in more detail, an insect has a small hole or spiral along the side of the abdomen, through which oxygen and carbon dioxide exchange and moisture retention can be controlled. The air that enters through the tongue spreads into the body and is supplied to the organ. Therefore, when an insect lacks oxygen or an appropriate amount of carbon dioxide is accumulated in the body by the hypoxic insecticidal method, the insect opens the gate and sucks oxygen. However, when oxygen is excessively depleted, it is left open due to dryness of the body due to rapid evaporation of water (7-10 times faster than when it is closed), and breathing increases at high temperature, Lt; / RTI >

Insects have a different rate of evaporation of water in the body depending on oxygen concentration, temperature and humidity during the experiment of hypoxic concentration insecticide method. In other words, insects have insufficient oxygen, have a high temperature or a low humidity, so that when they are dried, water in the body increases more rapidly and they are insecticide in a short time. Therefore, when the concentration of oxygen, temperature and humidity are appropriately adjusted at the time of insecticide, a complete insecticide can be expected.

On the other hand, the hypoxic concentration insecticide method uses an inert gas such as nitrogen, argon or helium to suppress or control pests. In addition, the hypoxic-concentration insecticide method has been used in various systems depending on the size and quantity of the cultural material to be insect-treated, and a small or medium-sized bag system, a large tent system, a bubble system, and a chamber system are most commonly used. This is explained in more detail as follows.

Small or medium-sized bags or large tent systems and bubble systems can be applied according to the size of cultural properties. In the thin film pack made of oxygen-opaque film or aluminum thin film, cultural property is added, then inert gas is injected to remove oxygen It is put together with oxygen scavenger and oxygen indicator, or only oxygen scavenger and oxygen indicator are put, heat sealed and insect treatment for a certain time. In the case of the chamber system, a system for injecting an inert gas after inserting a cultural material into a metal material chamber is used for insecticidal action.

However, in the general chamber system described above, inert gas is injected into the chamber, and the chamber is pushed out by the inert gas to be exhausted, so that the inert gas can not be completely filled in the chamber, and inert gas is supplied at the same speed There is a problem that the operation can not be started quickly.

In addition, since the humidity and the temperature of the chamber can not be controlled, not only the problem of causing a change in the cultural property but also the insecticidal time of the insect is prolonged.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and an object of the present invention is to provide a hypoxic insecticidal apparatus for preserving cultural heritage, in which an inert insecticidal gas can be injected while a chamber is evacuated.

Another object of the present invention is to provide a hypoxic insecticide for preserving cultural heritage, which can supply insecticidal gas at a different speed before or during driving.

In order to accomplish the above object, the present invention provides a refrigerator comprising: a chamber in which an interior is hermetically sealed, a rotary shaft is provided and a door is opened and closed while being rotated about a rotation axis; A locker for locking the door of the chamber; A gas removal unit for removing the gas filled in the chamber; An insecticidal gas supply unit for supplying insecticidal gas necessary for insecticide of the cultural property to the chamber; An exhaust unit for exhausting the insecticidal gas supplied into the chamber or the air inside the chamber to the outside of the chamber; And a controller for controlling operations of the exhaust unit, the gas elimination unit and the insect gas supply unit.

The locker includes, for example, a handle rotatably installed on the door; A rod installed on the door and moving by rotation of the handle; A converter for converting rotational motion of the knob to linear motion for movement of the rod and providing it to the rod; And a holder which is provided in the chamber and is located outside the door and in which the end of the rod moving by the transducer is inserted and held.

The converter includes, for example, a pinion connected to the handle and rotated together with the handle; And a rack engaged with the pinion and converting the rotational motion of the pinion into a linear motion and providing the same to the rod.

The gas removal unit may be composed of, for example, at least one of an air intake fan or a vacuum pump that sucks air or insecticidal gas charged into the chamber and supplies the air to the exhaust unit.

The insecticidal gas supply unit may comprise, for example, at least one gas cylinder storing the insecticidal gas; At least one supply pipe for supplying an insecticidal gas of the gas cylinder to the chamber; And a control valve for controlling a flow rate of the supply pipe by a control signal of the controller.

The gas cylinder may include, for example, a liquid gas cylinder connected to one of the supply lines and storing a liquid insect gas; And a gas-phase gas cylinder connected to the other one of the supply pipes and storing a gaseous insect gas.

The present invention further includes an additional feeder connected to the gas cylinder to supply the chamber with insecticidal gas of the gas cylinder at a different rate than the feed tube that feeds the chamber with the insecticidal gas.

The additional supply unit may include, for example, a bypass pipe for bypassing the insect gas of the supply pipe to the chamber at a flow rate different from that of the supply pipe to supply the insecticidal gas to the chamber at a higher or lower speed than the supply rate of the supply pipe; A bypass valve installed in the bypass pipe for interrupting a flow rate of the bypass pipe; And a guide valve that operates in an alternate state with the bypass valve and interrupts the supply pipe to guide the insecticidal gas of the supply pipe to the bypass pipe.

The exhaust unit may include, for example, an exhaust pipe communicating with the chamber and exhausting insecticidal gas or air of the chamber to the outside of the chamber.

In the present invention as described above, since the gas elimination unit forcibly removes the air inside the chamber to evacuate the chamber, and then the insecticidal gas supply unit supplies the insecticidal gas to the chamber, the insecticidal gas is promptly In addition to being able to charge, the insecticide gas can be completely charged into the chamber, and the chamber can be maintained in the hypoxic state by the insecticide gas, which makes it possible to easily insect pests that damage the cultural property.

In addition, since the door of the chamber is firmly locked by the locker, the vacuum state of the chamber can be stably maintained, as well as the leakage of insect gas can be prevented. In addition, since the rod of the locker is moved by the rotation of the handle, It is possible to easily lock the door, and furthermore, since the converter is constituted by the pinion and the rack, the converter can be easily manufactured.

In addition, the number of components can be reduced because the chamber can be evacuated with an intake fan or the insecticidal gas filled in the chamber can be exhausted.

In addition, since the control valve controls the flow rate of the supply pipe for supplying the insecticidal gas of the gas cylinder to the chamber, the supply amount of the insecticidal gas can be automatically controlled.

In addition, since the gas bomb is composed of a liquid gas cylinder and a gas cylinder, it is possible to shorten the charging time by filling the chamber with insect gas in the gas phase before operation. In the course of driving, the insecticide gas corresponding to the insecticide gas leaked from the chamber Since the chamber can be charged in a liquid gas bomb, the quantity of the gas-phase gas cylinder can be reduced, and the insect gas can be continuously charged into the chamber, so that the hypoxic environment of the chamber can be stably maintained during the insect time.

Moreover, the insect gas can be supplied to the chamber at a higher or lower speed than the supply rate of the supply pipe through the bypass pipe, so that the insect gas can be injected into the chamber at a desired speed.

In addition, since the exhaust unit is constituted by an exhaust pipe and air or insect gas of the chamber is exhausted to the outside of the chamber, the exhaust pipe can be commonly used for exhausting air or insecticidal gas.

1 is a front view of a hypoxic insecticide for preserving cultural properties according to an embodiment of the present invention;
FIG. 2 is a hydraulic circuit diagram of the insecticide device shown in FIG. 1; FIG.
Figure 3 is a front view of the chamber shown in Figure 1;
4 is an enlarged perspective view of a portion of the door shown in Fig. 3; Fig. And
Fig. 5 is a perspective view schematically showing the opening and closing state of the door shown in Fig. 3; Fig.

Hereinafter, a hypoxic insecticidal apparatus for preserving cultural properties according to an embodiment of the present invention will be described with reference to FIGS. 2 to 8 attached hereto.

A hypoxic insecticidal apparatus for preserving cultural properties according to an embodiment of the present invention includes a chamber 10, a rocker 20 and a controller 30 as shown in Fig. 1, and a gas elimination unit, an insect gas supply unit and an exhaust unit .

The chamber 10 is made of a metal material or a plastic panel with a built-in heat insulating material such as glass wool, and the inside is hermetically sealed as shown in Fig. 1, and a rotary shaft 12a is provided as shown in Fig. And a door 12 which is opened and closed while being rotated about the axis 12a. The chamber (10) has a built-in cultural property requiring the insecticide through the door (12). The chamber 10 is provided with a perforated plate P at the upper part and / or the lower part thereof as shown in FIG. 2 so that the inside air or gas can communicate with the outside while supporting the cultural material requiring insecticide. Such a chamber 10 may be provided with a shelf which is not shown in the figure, which is slidable or detachable.

The chamber 10 is preferably provided with a slider for slidably fixing the rotary shaft 12a of the door 12. [ The slider may include a door protrusion 13a and a lamination protrusion 13b as shown in Fig. 5, for example.

The door protrusion 13a is provided on the door 12 as shown in Fig. 5 and protrudes to the outside of the door 12, and the rotary shaft 12a is fixed in a vertical state. 5, the laminated projection 13b is provided in a protruded state in the chamber 10 and is laminated with the door protrusion 13a. A slot HL orthogonal to the longitudinal direction of the rotary shaft 12a is formed, 12a are fixed in a through state. The rotary shaft 12a moves along the slot HL of the lamination projection 13b when the door 12 is opened as shown in Fig. 5 (b). Accordingly, the door 12 easily separates the packing PK provided on the inner side surface from the packing groove PG of the chamber 10 by the slider. Consequently, the slider is an element that helps release the packing PK of the door 12 from the packing groove PG. In this case, since the part of the packing PK adjacent to the rotary shaft 12a is easily separated from the packing groove PG, the part of the packing PK adjacent to the rotary shaft 12a when the door 12 is opened is separated from the door 12, Is prevented from being damaged by rubbing against the edge of the piston (PG).

Here, the above-described slider may be provided with an inclined member 13c having an inclined surface IF as shown in Fig. The inclined member 13c is provided on the side of the door protrusion 13a so as to be spaced from the door protrusion 13a so that the edge ED of the door protrusion 13a faces the inclined surface IF. When the door 12 is opened, the inclined member 13c is brought into contact with the door projection 13a through the inclined surface IF while the edge ED of the door protrusion 13a collides with the inclined surface IF, as shown in Fig. 5 (b) (The longitudinal direction of the elongated hole) of the edge 13a. At this time, the door protrusion 13a is parallel to the elongated hole HL of the lamination projection 13b as shown in Fig. 5 (b) by the inclined member 13c, 12a. Therefore, the rotary shaft 12a is easily moved along the long hole HL.

On the other hand, the locker 20 locks the door 12 of the chamber 10. Such a rocker 20 includes, for example, a handle 21 and a rod 22 as shown in Fig. 1, a holder 24 as shown in Figs. 3 and 4, and a converter 23 described below .

The handle 21 is rotatably mounted on the door 12 as shown in Fig. The rod 22 is movably installed on the door 12 and moves as shown in Fig. 4 by the rotation of the knob 21. Fig. The holder 24 is provided in the chamber 10 as shown in Fig. 4 and is located outside the door 12. Fig. The holder 24 provides a hole through which the rod 22 is inserted on the outside of the door 12. That is, the holder 24 is inserted and held by the moving rod 22 as shown in Fig. 4 (b).

The transducer 23 converts the rotational motion of the knob 21 into a linear motion for movement of the rod 22 and provides it to the rod 22. The converter 23 can be configured to include, for example, a pinion 23a and a rack 23b as shown in FIG. The pinion 23a is connected to the handle 21 and rotated together with the handle 21 as shown in Fig. The rack 23b is meshed with the pinion 23a as shown enlarged in Fig. 4, and converts the rotational motion of the pinion 23a into a linear motion and provides it to the rod 22. Fig. Such a rack 23b is preferably integrally provided on the rod 22 as shown in FIG.

The converter 23 moves the rack 23b provided on the rod 22 while the pinion 23a is rotating when the knob 21 is rotated. Thus, the rod 22 can be moved by the transducer 23 when the handle 21 is rotated. The rod 22 is held by the holder 24 described above and locks the door 12 or unlocks the door 12 while returning to the original position after being detached from the holder 24.

Here, it is preferable that the rod 22 and the holder 24 described above are provided on all sides of the door 12 as shown in Fig. 4, the rod 22 can be moved while being supported by the rod guider 26 provided on the door 12. [ This load guider 26 is comprised of a bracket that provides a through-hole through the rod 22 to the door 12, as shown in Fig.

The locker 20 may further include a locking retainer that maintains the locking state of the rod 22 in accordance with the pressure of the chamber 10. The locking retainer may be constituted by a solenoid 25 provided with a plunger 25a which is coupled to the above-described pinion 23a and which locks the pinion as shown enlarged in the lower part of Fig. This solenoid 25 moves the plunger 25a while locking the pinion 23a while the operation of the solenoid 25 is controlled by the controller 30 so that the locker 20 remains locked when the pressure of the chamber 10 is high . As a result, the handle 21 is not rotated as the pinion 23a is locked. Therefore, the door 12 is not opened when the pressure of the chamber 10 is high.

On the other hand, the gas removal unit described above removes the gas filled in the chamber 10. That is, the gas removal unit removes the air or the insecticide gas filled in the chamber 10. Such a gas removal unit may be, for example, at least one of the suction fan 71 and the vacuum pump 72 as shown in Fig. 2 for sucking the air or insecticidal gas filled in the chamber 10 into an exhaust unit to be described later It can be composed of one.

On the other hand, the insect gas supply unit described above supplies the insect gas to the chamber 10 for the insecticide of the cultural property. This insect gas supply unit may comprise, for example, at least one gas cylinder 52, at least one feed pipe 54 and a control valve 56, as shown in FIG.

The gas cylinder 52 stores an inert insect gas such as nitrogen, helium or argon. The gas bomb 52 is connected to one of the supply pipes 54 and connected to the other of the liquid gas bomb 52b and the supply pipe 54 in which liquid insecticidal gas is stored, And a gas-phase gas cylinder 52a storing an insect gas of a gas phase.

The liquid gas bomb 52b is preferably constructed as a single unit as shown in the figure. Since the gas bomb 52a is in a gaseous state, it is preferable that the gas bomb 52a is composed of a plurality of gas bombs . It is preferable that the gas-phase gas cylinder 52a is sequentially exhausted by a control valve 56, which will be described later, which is controlled by the controller 30 when the gas- That is, the gas-phase gas cylinder 52a is preferably operated in the order that the next one is operated when one is exhausted by the control valve 56. [ At this time, as shown in FIG. 2, the controller 30 is connected to the plurality of gas-phase gas cylinders 52a to individually measure the outlet-side pressure of the supply pipe 54 or the gas-phase gas cylinder 52a, The gas-phase gas cylinders 52a are operated in the exhausted order as the pressure signals are applied from the plurality of pressure sensors S1. The pressure sensor S2 may also be installed in the liquid gas cylinder 52b as shown in FIG. 2 to transmit the present pressure of the liquid gas cylinder 52b to the controller 30, that is, the residual amount of the liquid insecticide gas. As a result, the gas-phase gas cylinder 52a can be configured to be exhausted in sequence by the pressure sensor S2 and the controller 30 in a plurality of configurations. Further, the liquid gas cylinder 52b may be constituted by one unit. Of course, the liquid gas cylinders 52b may be operated in such a manner as to consist of a plurality of gas cylinders 52a and sequentially exhausted in the manner as described above.

Here, the gas-phase gas cylinder 52a and the liquid-phase gas cylinder 52b may be simultaneously operated (gas-exhausted), but alternatively, it is preferable that they operate alternately alternately. The gas-phase gas cylinder 52a is used in the initial charging to fill the chamber 10 with the insecticidal gas because the gas-insecticidal gas is filled and can supply the insecticidal gas to the chamber 10 quickly. The liquid gas cylinder 52b is operated to replenish the insecticidal gas during operation, that is, the insecticide gas charged in the chamber 10 is slightly consumed or slightly leaks out of the chamber 10. The gas-phase gas cylinder 52a and the liquid-phase gas cylinder 52b are alternately operated by the pressure sensor S2 and the controller 30 described above.

The gas-phase gas cylinder 52a and the liquid-phase gas cylinder 52b may be embedded in the cabinet 81 as shown in Figs. That is, in the embodiment of the present invention, the cabinet 81 in which the gas cylinder 52 is installed may be provided. The cabinet 81 may be provided with a cabinet exhaust pipe 82 and a gauge 84 as shown in FIGS. The cabinet exhaust pipe (82) exhausts insecticidal gas leaking into the cabinet (81) to the outside. 1, the cabinet exhaust pipe 82 communicates with an exhaust pipe 60 of an exhaust unit, which will be described later, to exhaust the insecticidal gas through the exhaust pipe 60.

The gauge 84 is installed in the cabinet 81 as shown in FIG. 1 to display the flow rate of the cabinet exhaust pipe 82 by the pressure of the cabinet exhaust pipe 82. As shown in FIG. 2, the gauge 84 displays the flow rate of the cabinet exhaust pipe 82 by a manometer 84a provided in a cabinet exhaust pipe 82 as a bypass pipe type branch pipe. Therefore, the driver can confirm that the insect gas leaks through the gauge 84, thereby preventing a safety accident.

Here, the cabinet 81 may be provided with a gas sensing sensor S7 as shown in FIG. Therefore, the cabinet 81 can more accurately confirm that the insecticidal gas is leaked. The gas detection sensor S6 may be provided on the outside of the chamber 10 as shown in FIG. 1 to confirm that the insect gas leaks to the outside of the chamber 10.

On the other hand, the above-mentioned supply pipe 54 is connected to the gas cylinder 52 and the chamber 10 as shown in FIG. 2, and supplies the insecticidal gas of the gas cylinder 52 to the chamber 10. The supply pipe 54 is constituted in a quantity corresponding to the quantity of the gas cylinder 52 as shown in Fig.

On the other hand, the above-described control valves 56 are installed in the respective supply pipes 54 as shown in Fig. The control valve 56 controls the flow rate of the supply pipe 54 by the control signal of the controller 30. [ That is, the control valve 56 regulates the amount of the insecticidal gas flowing into the supply pipe 54, or supplies or stops the insecticidal gas.

On the other hand, the above-described exhaust unit exhausts the insecticidal gas supplied to the chamber 10 or the internal air of the chamber 10 to the outside of the chamber 10. 1, the exhaust unit is preferably formed of an exhaust pipe 60 communicating with the chamber 10 to exhaust the insecticidal gas or air of the chamber 10 to the outside of the chamber 10. The exhaust unit may further include an exhaust fan 60a that provides negative pressure to the exhaust pipe 60 as shown in FIG. 1 to help exhaust the exhaust pipe 60. [

On the other hand, the above-described controller 30 controls the operation of the gas removal unit and the insecticidal gas supply unit described above. This controller 30 provides a panel for controlling the operation of the chamber 10 in front of the chamber 10 as shown in Fig.

An embodiment of the present invention is also directed to a method of controlling an insecticidal gas of a gas bomb 52 at a different rate than a supply conduit 54 connected to the gas bomb 52 described above to supply the insecticidal gas to the chamber 10. [ And may further include an additional feeder that feeds. This additional feeder may comprise a bypass pipe 72, a bypass valve 74 and a pilot valve 76, as shown in FIG.

2, the bypass pipe 72 is branched from the supply pipe 54 and formed with a different diameter from the supply pipe 54 so that the insect gas of the supply pipe 54 is supplied to the chamber 54 at a different flow rate than the supply pipe 54 10). Thus, the bypass pipe 72 supplies the insect gas to the chamber 10 at a higher speed or at a lower speed than the supply speed of the supply pipe 54. The bypass pipe (72) supplies insecticidal gas at a high speed when the pipe diameter is larger than the supply pipe (54), and supplies insecticidal gas at a low speed when the pipe diameter is smaller than the supply pipe (54). When the bypass pipe 72 is formed to have a larger diameter than the supply pipe 54, the bypass pipe 72 is connected to the outlet of the bypass pipe 72, and the connection pipe 54a, which constitutes a part of the supply pipe 54, It is obvious that it should be formed with a pipe diameter equal to or larger than the pipe 72.

Here, it is preferable that the above-mentioned bypass pipe 72 is formed larger than the pipe diameter of the supply pipe 54 so that the insecticidal gas is supplied at high speed.

The bypass valve 74 is installed in the bypass pipe 72 as shown in FIG. 2 to interrupt the flow rate of the bypass pipe 72. The guide valve 76 is installed in the supply pipe 54 branched from the bypass pipe 72 as shown in FIG. 2 and interlocks with the supply pipe 54 while operating in an alternating manner with the bypass valve 74. Therefore, the guide valve 76 guides the insecticidal gas flowing from the supply pipe 54 to the connection pipe 54a to the bypass pipe 72. [ That is, in the bypass pipe 72, when the supply pipe 54 is shut off by the guide valve 76, the insect gas of the supply pipe 54 flows. Thus, the bypass pipe 72 supplies the insecticidal gas to the chamber 10 at a high speed when the guide valve 76 blocks the supply pipe 54. Particularly, the bypass pipe 72 supplies the insecticidal gas of the gas-phase gas cylinder 52a to the chamber 10 at a high speed when the insect-proof gas is initially charged in the chamber 10. [

Meanwhile, the embodiment of the present invention may further include a humidity controller for adjusting the humidity of the chamber 10 and / or a temperature controller for adjusting the temperature of the chamber 10. The humidity controller may comprise, for example, a steamer 91 that provides steam inside the chamber 10 as shown in FIG. The steam generator 91 is provided by mixing 2 to 8 parts by weight with respect to 100 parts by weight of the insecticidal gas supplied through the supply pipe 54. The steam generator 91 supplies steam to the chamber 10 through a steam supply pipe 91b connected to the supply pipe 54 as shown in FIG. The diameter of the steam supply pipe 91b is smaller than the diameter of the supply pipe 54 and the steam generator 91 mixes 2 to 8 parts by weight of steam with respect to 100 parts by weight of the insect gas. Since the steam supply pipe 91b is formed at a ratio of 0.02 to 0.08 times the diameter of the supply pipe 54, the above-described amount of steam can be mixed into the insect gas.

The steam generator 91 further includes an external discharge pipe 91a for discharging the steam at the time of overpressure to the outside as shown in FIG. Therefore, the steamer 91 operates safely even when overpressure occurs.

The steam generator 91 may be provided with a direct pipe 91c for directly supplying steam to the chamber 10 as shown in FIG. Therefore, the steamer 91 can supply the steam to the chamber 10 quickly. The direct pipe 91c is formed to have the same size as the steam supply pipe 91b.

The steam supply pipes 91b and 91a and the direct pipe 91c are provided with steam valves V1, V2 and V3 as shown in FIG. 2 so as to be connected to the steam valves V1, V2 and V3 The steam can be interrupted by.

On the other hand, the temperature controller described above may be configured by at least one of a heater 92 and a cooler 94 as shown in FIG. 2, for example. The heater 92 heats the chamber 10 by providing warmth inside the chamber 10. The cooler 94 provides cool air to the chamber 10 to cool the chamber 10.

The cooler 94 may be configured to provide cool air using the coolant, but is preferably configured such that the interior of the chamber 10 is not cooled below zero. To this end, the cooler 94 may include a low-temperature water pipe 94a and a chiller 94b as shown in Fig. The low-temperature water pipe 94a circulates the low-temperature water in the chamber 10. The chiller 94b provides low temperature water to the low temperature water pipe 94a. It is preferable that the chiller 94b provides low temperature water of about 1 占 폚 to 12 占 폚 to the low temperature water pipe 94a.

Here, the heater 92, the cooler 94, or the steamer 91 may be installed in the machine room 14 provided in the lower portion of the chamber 10 as shown in FIG.

As shown in FIG. 2, the embodiment of the present invention may include a sensor unit including at least one of a temperature sensor S3, a humidity sensor S5, a pressure sensor S2, and a concentration sensor S4 have. This sensor unit senses the temperature, humidity, pressure, oxygen concentration or insecticidal gas concentration inside the chamber 10 and applies it to the controller 30 described above. Accordingly, the controller 30 controls the operation of the heater 92 described above by the sensed temperature and controls the operation of the steamer 91 and the steam valves V1, V2, V3 described above by the sensed humidity And controls the operation of the suction fan 71 or the vacuum pump 72 or the steamer 91 of the gas removal unit according to the sensed pressure and controls the operation of the supply pipe 54 according to the detected oxygen concentration or the concentration of the insecticidal gas. The control valve 56 and the gas cylinder 52 of the engine. The controller 30 may control the operation of the steamer 91 by the temperature sensor S3 when the chamber 10 is heated by the steam of the steamer 91. [

On the other hand, the chamber 10 may be provided with a circulation fan 71a inside as shown in FIG. The circulating fan 71a circulates the inside air stream while rotating inside the chamber 10. [ Therefore, the chamber 10 can circulate the insecticidal gas therein.

In addition, the chamber 10 may be provided with an alarm for warning of danger while operating according to the pressure value of the pressure sensor S2 described above. 1, the buzzer 42 may be a buzzer installed in the chamber 10, or a speaker or a lamp 44 not shown in the figure. The buzzer 42 may be a controller, which receives a signal from the pressure sensor S2, (30). That is, the controller 30 operates the alarm in accordance with the pressure signal applied from the pressure sensor S2. Therefore, the driver can detect the danger. The controller 30 may operate the alarm according to the signal of the temperature sensor S3 described above.

Also, the chamber 10 may be provided with an emergency switch 46 as shown in Fig. The emergency switch 46 interrupts the operation of the insecticidal gas supply unit, the heater 92 and the steamer 91 through the controller 30. [ Then, the emergency switch 46 operates the above-described intake fan 71 to exhaust the insecticidal gas filled in the chamber 10 to the exhaust pipe 60.

Meanwhile, in the embodiment of the present invention, a bypass unit for bypassing and discharging insecticidal gas or air exhausted to the exhaust pipe 60 at a flow rate different from that of the exhaust pipe 60 may be provided. The bypass unit may include a bypass exhaust pipe 62, a flow rate shut-off valve 62a, and an exhaust pipe valve 62b as shown in FIGS.

As shown in FIG. 1, the bypass exhaust pipe 62 is connected to the exhaust pipe 60 by a pipe diameter different from the pipe diameter of the exhaust pipe 60. It is preferable that the bypass exhaust pipe 62 is formed to be smaller than the pipe diameter of the exhaust pipe 60 as shown for exhausting at a smaller flow rate than the exhaust pipe 60.

The flow rate control valve 62a is installed in the bypass exhaust pipe 62 as shown, and interrupts the flow rate of the bypass exhaust pipe 62. The exhaust pipe valve 62b operates alternately with the flow rate control valve 62a to intermittently exhaust the exhaust pipe 60 to guide the insect gas or air in the exhaust pipe 60 to the bypass exhaust pipe 62. That is, the exhaust pipe valve 62b closes the exhaust pipe 60 and guides the insecticidal gas or air in the chamber 10, which flows into the exhaust pipe 60, to the bypass exhaust pipe 62. Therefore, the bypass exhaust pipe 62 exhausts insect gas or air at a flow rate smaller than that of the exhaust pipe 60.

This bypass unit normally exhausts the insecticidal gas or air in the chamber 10 by the bypass exhaust pipe 62. However, when the bypass valve needs to quickly evacuate air or insect gas in the chamber 10, the bypass valve 62a is closed by operating the flow rate valve 62a. Therefore, the insect gas or air is quickly exhausted through the exhaust pipe 60 formed to have a larger diameter than the bypass exhaust pipe 62.

Here, the exhaust pipe 06 and / or the bypass exhaust pipe 62 may be provided with a conventional damper 63 for controlling the flow rate as shown in FIG. 1, the damper 63 is formed of a plate member rotatably installed in the exhaust pipe 60 or the bypass exhaust pipe 62 in a horizontal state. The damper 63 is provided with an angle scale 64, Can be adjusted. The rotational angle of the damper 63 is adjusted when the knob 63a connected to the rotational shaft is operated. Since the damper 63 is easily understood by those skilled in the art, a detailed description thereof will be omitted.

1, according to the embodiment of the present invention constructed as described above, as shown in FIG. 1, as the handle 21 installed on the door 12 of the chamber 10 is rotated, the door 12 is opened do. At this time, as the door protrusion 13a is formed parallel to the lamination protrusion 13b by the guide of the inclined member 13c formed with the inclined plane IF as shown in FIG. 5B, The rotary shaft 12a moves along the elongated hole HL of the lamination projection 13b. Therefore, the door 12 is easily opened without damaging or leaving the packing PK.

The chamber 10 has a built-in cultural property such as an organic material such as a cultural material that needs to be insect-proofed as the door 12 is opened. The chamber 10 is locked with the door 12 as the door 12 is closed as shown in Fig. 5 (a) and then the handle 21 is rotated as shown in Fig. The door 12 moves the rack 23b while the pinion 23a is rotated by the knob 21 as shown in an enlarged view in the upper part of Fig. 3 and the rack 23b moves the rod 22, The holder 24 is inserted and held by the end portion of the holder 22 as shown in FIG. At this time, the rod 22 is stably inserted into the holder 24 by the rod guider 26 as shown in Fig.

The chamber 10 is opened and closed by the air intake fan 71 of the gas removal unit as shown in Fig. 2 or the vacuum pump 72 as shown in Fig. 2 after the door 12 is locked through the exhaust pipe 60 of the exhaust unit. do. Thus, the chamber 10 is evacuated inside by the gas removal unit. At this time, the chamber 10 keeps the bypass exhaust pipe 62 shown in Figs. 1 and 2 closed for rapid exhaust. After the vacuum is completed, the chamber 10 maintains the closed state of both the exhaust pipe 60 and the bypass exhaust pipe 62.

After the vacuum is completed, the chamber 10 is supplied with an inert insect gas from the gas cylinder 52 of the insect gas supply unit as shown in Fig. That is, the chamber 10 is charged with insecticidal gas and becomes a low-oxygen state. Particularly, the chamber 10 is in a low-oxygen state with an oxygen concentration of about 0.01% to 0.07% so that the respiration of the insect pests is almost impossible. At this time, the controller 30 operates the control valve 56 of the supply pipe 54 connected to the vapor-phase gas cylinder 52a to charge the chamber 10 with the insect-fighting gas. Thus, the chamber 10 is quickly filled with the insecticidal gas at the beginning (the start of operation). Of course, the chamber 10 is filled with the insecticidal gas more quickly by the internal vacuum pressure.

The chamber 10 is opened when the controller 30 operates the bypass valve 74 to open the bypass pipe 72 as shown in Fig. 2 and to open the bypass pipe 72 of the guide pipe 54 of the supply pipe 54 connected to the connection pipe 54a The insect gas is charged more quickly when the supply pipe 54 is shut off by operating the switch 76. At this time, since the diameter of the bypass pipe 72 is larger than that of the supply pipe 54, the insect gas is supplied to the chamber 10 at a higher rate than the supply pipe 54. Thus, the chamber 10 is charged with insecticidal gas more rapidly.

The chamber 10 is supplied with steam from the steamer 91 as shown in Fig. 2 so as to prevent deformation of the cultural material embedded therein. At this time, the steamer 91 supplies 2 to 8 parts by weight of steam to 100 parts by weight of the insecticidal gas supplied to the chamber 10 due to the diameter of the steam supply pipe 91b. The steam generator 91 continuously supplies steam to the chamber 10 so as to prevent pests of the chamber 10 from being deformed while preventing the deformation of the cultural property so that the humidity inside the chamber 10 is increased. Steam is supplied at about 10% to 20% of the total amount of gas. Therefore, the cultural property embedded in the chamber 10 is prevented from being deformed by the appropriate humidity by the steam, and the pest is insecticide due to the decrease of the humidity.

The chamber 10 can be heated by the heater 92 to double the insecticidal effect and cooled by the cooler 94 when it is overheated. At this time, the cooler 94 prevents the chamber 10 from being cooled down to a low temperature while cooling the chamber 10 to a low temperature. The heater 92 heats the chamber 10 so that the internal temperature of the chamber 10 can be insect-proofed and the deformation of the cultural property is prevented so that the internal temperature of the chamber 10 is about 12 ° C to 25 ° C. Such a heater 92 is not omitted or operated when the internal temperature of the chamber 10 is about 12 to 25 占 폚 by the steam of the steamer 91 described above.

On the other hand, the controller 30 controls the control valve (not shown) of the supply pipe 54 in accordance with the detection signal of the pressure sensor S2 as shown in Fig. 2 when one of the gas- 56 are operated to operate the gas-phase gas cylinder 52a in the following sequence. When the insecticidal gas leaks after the insecticidal gas is completely filled in the chamber 10 and the gas concentration is detected to be lowered from the concentration measuring sensor S4 shown in Fig. 2, the controller 30 controls the liquid gas cylinder 52b ) To constantly replenish insecticidal gas during operation. Therefore, the chamber 10 can perform insecticide smoothly. At this time, insect pests that are parasitic to the cultural property are opened due to lack of oxygen by insect gas. However, insect pests are killed due to lack of oxygen due to increase in respiration, so that the moisture in the body evaporates rapidly due to the continuous opening of the gates. In particular, it dries and dies more quickly due to the heat of the steam or the heat of the heater. Even if the moisture is introduced by the steam, the insecticidal gas is insufficiently dried because the amount of steam supplied to the chamber 10 is extremely small compared with the amount of the insecticidal gas supplied to the chamber 10.

On the other hand, the controller 30 operates the steamer 91 according to the humidity value of the humidity sensor S4 shown in Fig. 2, operates the heater 92 according to the temperature value of the temperature sensor S3, The gas cylinder 52 is operated according to the measured value of the sensor S5. When the chamber 10 is operated, the controller 30 operates the circulating fan 71a shown in Fig. 2 to circulate the insecticidal gas therein. Therefore, the chamber 10 performs insecticide more smoothly by circulating insect gas. Particularly, since the chamber 10 operates the steamer 91, the heater 92 and the gas cylinder 52 by the controller 30, the chamber 10 is operated when the humidity environment and the temperature environment and the hypoxic environment set for the insecticide are satisfied And the set environment listed can be maintained stably during the operation time. That is, the chamber 10 is operated by the controller 30 when a humidity of about 10% to 20%, a temperature of about 12 ° C to 25 ° C, and a low oxygen concentration of about 0.01% to 0.07% are satisfied, It can be maintained continuously.

On the other hand, when the measured value of the pressure sensor S2 or the temperature sensor S3 is equal to or higher than the set safe range, or when it is detected that the gas is leaked from the gas sensor S6, 46 is operated, the buzzer 42 or the lamp 44 shown in FIG. 1 is operated to warn of a danger. The controller 30 stops the operation of the gas cylinder 52 and the steamer 91 and the heater 92 and operates the plunger 25a of the solenoid 25 as shown enlarged in the lower part of Fig. The pinion 23a is locked to prevent the opening of the door 12 and the insufflation gas of the chamber 10 is quickly discharged through the exhaust pipe 60 by operating the suction fan 71 or the vacuum pump 72 shown in Fig. Exhaust. At this time, the bypass exhaust pipe 62 is closed because the diameter of the bypass pipe 62 is smaller than that of the exhaust pipe 60 and the amount of perfusion is small. However, the bypass exhaust pipe 62 is opened when the normal operation is completed, and gradually exhausts the insecticidal gas.

The bypass exhaust pipe 62 is partially opened by the flow rate shut-off valve 62a and the exhaust pipe valve 62b controlled by the controller 30 so that the insecticidal gas filled in the chamber 10 is not stagnated, A small amount of the insecticidal gas can be continuously exhausted until the operation is stopped. At this time, the chamber 10 is replenished with insect gas exhausted by the gas cylinder 52. In this case, since the chamber 10 flows without stagnating the insecticidal gas, insecticidal gas can be continuously supplied to various parts of the cultural property, thereby improving the insecticidal performance.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to be illustrative of the present invention and are not intended to limit the scope of the present invention. Change, partial omission, or supplement). In addition, the above-described embodiments may combine some or many of the features with each other. Therefore, the structure and configuration of each component shown in the embodiments of the present invention can be implemented by modifications or combinations, and it goes without saying that modifications and combinations of these structures and configurations fall within the scope of the appended claims of the present invention.

10: chamber 12: door
13a: door projection 13b: lamination projection
20: Rocker 21: Handle
22: Load 23: Converter
23a: pinion 23b: rack
24: Holder 30: Controller
42: buzzer 44: lamp
46: emergency switch 52: gas cylinder
52a: vapor gas cylinder 52b: liquid gas cylinder
54: supply pipe 56: control valve
60: Exhaust pipe 62: Bypass exhaust pipe
62a: Flow rate control valve 62b: Exhaust pipe valve
72: bypass pipe 74: bypass valve
76: Guide Valve 81: Cabinet
82: Exhaust pipe 84: Gauge
84a: Manometer 91: Steamer
94: cooler

Claims (8)

A chamber in which the inside is hermetically sealed, a rotary shaft is provided and the door is opened and closed while being rotated about the rotary shaft, and a cultural material requiring insecticide is installed through the door;
A locker for locking the door of the chamber;
A gas removal unit for removing the gas filled in the chamber;
An insecticidal gas supply unit for supplying insecticidal gas necessary for insecticide of the cultural property to the chamber;
An exhaust unit for exhausting the insecticidal gas supplied into the chamber or the air inside the chamber to the outside of the chamber; And
And a controller for controlling the operation of the exhaust unit, the gas elimination unit and the insect gas supply unit,
Wherein the locker comprises:
A handle rotatably installed on the door;
A rod installed on the door and moving by rotation of the handle;
A converter for converting rotational motion of the knob to linear motion for movement of the rod and providing it to the rod; And
And a holder which is provided in the chamber and is located outside of the door and in which an end of the rod moving by the transducer is inserted and held. delete 2. The apparatus of claim 1,
A pinion connected to the handle and rotated together with the handle; And
And a rack which is meshed with the pinion and converts the rotary motion of the pinion into a linear motion and provides the rotary motion to the rod. The gas-removing unit according to claim 1,
And a vacuum pump for sucking the air or insecticidal gas charged into the chamber and supplying the air or the insecticidal gas to the exhaust unit. A chamber in which the inside is hermetically sealed, a rotary shaft is provided and the door is opened and closed while being rotated about the rotary shaft, and a cultural material requiring insecticide is installed through the door;
A locker for locking the door of the chamber;
A gas removal unit for removing the gas filled in the chamber;
An insecticidal gas supply unit for supplying insecticidal gas necessary for insecticide of the cultural property to the chamber;
An exhaust unit for exhausting the insecticidal gas supplied into the chamber or the air inside the chamber to the outside of the chamber; And
And a controller for controlling the operation of the exhaust unit, the gas elimination unit and the insect gas supply unit,
The insecticidal gas supply unit includes:
At least one gas cylinder in which the insecticidal gas is stored;
At least one supply pipe for supplying an insecticidal gas of the gas cylinder to the chamber; And
And a control valve for controlling a flow rate of the supply pipe by a control signal of the controller,
Further comprising an additional feeder connected to the gas cylinder to supply the chamber with insecticidal gas of the gas cylinder at a rate different from the feed tube feeding the chamber with insecticidal gas,
Wherein the additional feeder comprises:
A bypass pipe for bypassing the insecticidal gas of the supply pipe to the chamber at a flow rate different from that of the supply pipe to supply the insecticidal gas to the chamber at a higher speed or at a lower speed than the supply speed of the supply pipe;
A bypass valve installed in the bypass pipe for interrupting a flow rate of the bypass pipe; And
And a guide valve that operates in an alternating manner with the bypass valve and interrupts the supply pipe to guide the insecticidal gas of the supply pipe to the bypass pipe. 6. The gas bomb of claim 5,
A liquid gas cylinder connected to one of the supply pipes and storing a liquid insecticidal gas; And
And a meteorological gas cylinder connected to the other one of the supply pipes and storing a gaseous insecticidal gas. delete 6. The method according to claim 1 or 5,
The exhaust unit includes:
And an exhaust pipe communicating with the chamber and exhausting insecticidal gas or air of the chamber to the outside of the chamber.

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