JP6427209B2 - Microbe control air conditioning system - Google Patents

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to an air conditioning system, and more particularly to an air conditioning system equipped with a charged particle generator for suppressing microorganisms.

  A large number of air cleaners using charged particles have been put into practical use conventionally. For example, the air cleaner disclosed in Japanese Patent Application Laid-Open No. 2012-75484 (Patent Document 1) generates an electrolyzed water mist from electrolyzed water. In this air cleaner, it is possible to obtain a strong sterilization effect by increasing the concentration of hypochlorous acid and OH radicals in the electrolyzed water.

  The ion generating unit disclosed in JP 2010-29553 A (Patent Document 2) sucks in air from an air suction port and blows out air containing ions generated in an ion generating portion from an air outlet. Thereby, air containing ions is diffused into the room to remove airborne bacteria in the room. The air cleaner disclosed in Japanese Patent Application Laid-Open No. 2011-226744 (Patent Document 3) discharges air containing charged water droplets composed of water and nanocolloids into a room to remove suspended substances in the room.

JP, 2012-75484, A Unexamined-Japanese-Patent No. 2010-29553 JP, 2011-226744, A

  In view of the recent power situation, power saving in factories and homes is required more than ever. The total power consumed by the air conditioning system in factories and homes is enormous. Therefore, it is desirable to reduce the power consumption of the air conditioning system.

  The present invention has been made in view of such circumstances, and realizes a hygienic environment by the bactericidal effect of the charged particles generated by the charged particle generating device, and reduces the power consumption and controls the microorganisms. The purpose is to provide a harmonized system.

According to one aspect of the present invention, a microorganism control air conditioning system comprises an air conditioner and a charged particle generator. The air conditioner regulates the temperature in the environment to the set temperature. The charged particle generator generates charged particles by discharge to deliver the charged particles into the environment. The charged particles include positive ions and negative ions generated by ionizing water vapor in air by plasma discharge, and the positive ions are H ⁺ (H ₂ O) _n when n is any natural number. The negative ion is O ₂ ⁻ (H ₂ O) _m, where m is an arbitrary natural number. The air conditioning system for suppressing microbes determines the first temperature as the set temperature of the air conditioner when the amount of charged particles delivered is the first amount when the air conditioner is cooling, and the amount of charged particles delivered Is a second delivery amount larger than the first delivery amount, the set temperature is set to a second temperature higher than the first temperature.

  Preferably, the microorganism control air conditioning system defines a first temperature as a set temperature of the air conditioner in a stop state of the charged particle generator.

  According to the present invention, it is possible to provide an air conditioning system for suppressing microorganisms while realizing a hygienic environment by the bactericidal effect of the charged particles generated by the charged particle generator, and reducing power consumption. .

It is a schematic diagram which shows the structure of the air conditioning system which concerns on embodiment of this invention. It is an external appearance perspective view which shows an example of a structure in the state which closed the louver of the charged particle generator in the air conditioning system shown in FIG. It is an external appearance perspective view which shows an example of a structure in the state which opened the louver of the charged particle generator shown in FIG. It is a perspective view which shows an example of an internal structure of the charged particle generator shown in FIG. It is an external appearance perspective view which shows an example of a structure of the charged particle generation unit in the charged particle generator shown in FIG. It is a top view which shows an example of an internal structure of the charged particle generator shown in FIG. It is a top view which expands the blowing port shown in FIG. 6, and shows the outline. It is sectional drawing which shows the cross section of the blower outlet which follows the VIII-VIII line shown in FIG. It is sectional drawing which shows the outline of the cross section of the blower outlet which follows the IX-IX line shown in FIG. It is sectional drawing which shows another example of a structure of the blower outlet shown to the figure. It is a flowchart for demonstrating the detection process of the microorganisms which the microorganisms detection apparatus in the air conditioning system shown in FIG. 1 performs. It is a schematic diagram for demonstrating the principle of the collection process in the flowchart shown in FIG. It is a schematic diagram for demonstrating the principle of the fluorescence measurement process before a heating in the flowchart shown in FIG. It is a schematic diagram for demonstrating the principle of the fluorescence measurement process after a heating in the flowchart shown in FIG. It is a schematic diagram for demonstrating the principle of the refresh process in the flowchart shown in FIG. It is a flowchart for demonstrating control of the control apparatus shown in FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and the description thereof will not be repeated.

  In the embodiments described below, the air conditioning system is applied to a factory building of a factory that processes food. Under the Food Sanitation Act, the environmental conditions necessary for food processing are defined, for example, by the Hygiene and Environmental Methods (HACCP). In food processing plants, in order to suppress the activity of microorganisms suspended in the air (including bacteria and viruses, hereinafter referred to as suspended microorganisms) and microorganisms attached to food (hereinafter referred to as attached microorganisms), It is common to keep the temperature low (eg 15 ° C.). Therefore, the power consumption of the air conditioning system is particularly large in a food processing plant. In addition, the physical load is large for workers who work in a low temperature environment. In addition, what the air conditioning system which concerns on this invention can apply is not limited to a factory building.

FIG. 1 is a schematic view showing a configuration of an air conditioning system according to an embodiment of the present invention. Referring to FIG. 1, the air conditioning system 200 includes an air conditioner 202, a charged particle generation device 100, a control device 204, and a microorganism detection device 500. The factory building 201 is provided with a ceiling 201R, a door 201D, and a food processing facility 203. Worker (not shown)
Enters and leaves the factory building 201 (within the environment) from the door 201D. The food processing facility 203 is, for example, a work bench or processing apparatus for processing food.

  The air conditioner 202 and the charged particle generation device 100 are a so-called ceiling-embedded type. In the ceiling 201R of the factory building 201, through holes are provided corresponding to the air conditioner 202 and the charged particle generator 100, respectively. The air conditioner 202 regulates the temperature in the environment so that the temperature in the environment reaches the set temperature.

The charged particle generator 100 is configured to be capable of generating both positive ions and negative ions. The charged particle generation device 100 has four operation modes of weak / standard / full power / rapid in order of increasing generation amount of charged particles. In a space with a ceiling height of 3 m and a floor area of about 35 m ² , in the “standard mode”, the charged particle generator 100 can maintain each of the positive ion and negative ion concentrations at 25,000 / cm ^3. . In the “rapid mode”, the charged particle generation device 100 can set the concentration of each of positive ions and negative ions to 50,000 / cm ³ .

  The more the attached microorganisms, the more the suspended microorganisms are present, and the less the suspended microorganisms, the smaller the number of the attached microorganisms. In order to evaluate the amount of attached microorganisms (for example, the number of microorganisms per unit area), the microorganism detection apparatus 500 is installed, for example, on a wall near the food processing facility 203. Thus, the microorganism detection apparatus 500 detects the amount of suspended microorganisms around the food processing facility 203. This detection method will be described in detail later.

  The control device 204 is connected to the air conditioner 202, the charged particle generation device 100, and the microorganism detection device 500 to centrally control these devices. More specifically, the control device 204 acquires a detection result indicating the amount of microorganisms from the microorganism detection device 500. Based on the detection result, the control device 204 determines the set temperature of the air conditioner 202 and controls the charged particle generation device 100 to adjust the amount of charged particles sent into the environment. This control method will also be described in more detail later.

  FIG. 2 is an external perspective view showing an example of the configuration of the charged particle generation device 100 in the closed state of the louver in the air conditioning system 200 shown in FIG. FIG. 3 is an external perspective view showing an example of the configuration of the charged particle generation device 100 shown in FIG. 2 with the louver opened. FIG. 4 is a perspective view showing an example of the internal configuration of the charged particle generation device 100 shown in FIG.

  With reference to FIGS. 2 to 4, the charged particle generation device 100 includes a box-shaped case 1 whose one surface is open and a rectangular panel 2 mounted on the opening surface of the case 1. The charged particle generation device 100 is installed with the case 1 protruding from the through hole above the ceiling 201R (see FIG. 1). Thereby, the panel 2 is exposed to the ceiling surface. Similarly, the air conditioner 202 is installed so that only the panel is exposed to the ceiling surface.

  A rectangular air intake 10 is provided at the center of the panel 2. In the panel 2, the height dimension (thickness dimension) of the central portion is large, and the height dimension decreases from the central portion toward the peripheral portion. That is, the surface (front surface) of the panel 2 is inclined with respect to the surface of the inlet 10. At the periphery of the panel 2, rectangular air outlets 11 to 14 are provided. The louvers 21-24 which are wind direction adjustment boards are provided in each of the blower outlets 11-14.

The louvers 21 to 24 each have a rectangular shape having substantially the same size as the outlets 11 to 14 respectively. The louvers 21 to 24 are provided so as to circularly move in the forward and reverse directions around an axis along the edge of the outlets 11 to 14 on the central portion side of the panel 2. The louvers 21 to 24 are controlled by a louver control circuit (not shown). By closing the louvers 21-24, the outlets 11-1
4 are covered with louvers 21 to 24 respectively. On the other hand, by opening the louvers 21-24 at an appropriate angle (for example, the angle with respect to the surface of the inlet 10), air containing charged particles blown out from the outlets 11-14 strikes the inner side surface of the louvers 21-24. Thereby, the wind direction can be adjusted. In addition, air can be blown out in a direction from the central portion of the panel 2 toward the peripheral portion.

  In the vicinity of the blowout ports 11 to 14, LEDs 31 to 34 are provided corresponding to the blowout ports 11 to 14 respectively. For example, each of the LEDs 31 to 34 is provided between the periphery of the inlet 10 and the end of the outlets 11 to 14. The LEDs 31 to 34 notify the user of the abnormality or the need for inspection of the corresponding outlets 11 to 14. The LEDs 31 to 34 may be provided with a light guide member (not shown), for example, to illuminate a desired region of the outer surface of the louvers 21 to 24 with light when lit. As a result, regardless of the open and closed states of the louvers 21-24, a desired region of the outer surface of the louvers 21-24 can be illuminated, and visibility from the outside can be enhanced.

  A display panel 25 is provided on the front of the panel 2. The display panel 25 includes, for example, a plurality of LED lamps and a light receiving unit. The LED lamp for indicating that the charged particle generation device 100 is in operation, the LED lamp for notifying replacement of the charged particle generation unit, the abnormality such as the charged particle generation units 41 to 44, for the plurality of LED lamps It includes an LED lamp for notifying, or an LED lamp for notifying cleaning of the charged particle generation units 41 to 44 or a filter (not shown). The light receiving unit receives a signal from the remote control.

  The charged particle generation units 41 to 44 are respectively installed inside the outlets 11 to 14. The charged particle generation unit 41 will be representatively described below. The configuration of the other charged particle generation units 42 to 44 is the same as the configuration of the charged particle generation unit 41.

  FIG. 5 is an external perspective view showing an example of the configuration of the charged particle generation unit 41 in the charged particle generation device 100 shown in FIG. Referring to FIG. 5, charged particle generation unit 41 includes a box-shaped storage portion 411. In the storage unit 411, the charged particle generation unit 411a and the charged particle sensor 414 are stored.

  The charged particle generation unit 411a is a rectangular plate. The charged particle generation part 411a is provided with an electrode part 412 for generating negative ions in the vicinity of one end, and an electrode part 413 for generating positive ions in the vicinity of the other end. A voltage is periodically applied to each of the electrode portions 412 and 413 by a control circuit (not shown). The charged particle sensor 414 detects the amount of positive ions and negative ions generated by the electrode units 412 and 413.

  At one side end of the housing portion 411, a connector 415 for mechanically and electrically connecting the charged particle generation unit 41 is provided. At the other side end of the housing portion 411, a screw portion 416 for fixing the charged particle generation unit 41 to the case 1 is provided.

The charged particle generation unit 41 ionizes water vapor in the air by plasma discharge to generate H ⁺ (H ₂ O) _n (n is an arbitrary natural number) as positive ions and O ₂ ⁻ (H as negative ions). ₂ O) _m (m is an arbitrary natural number) is generated. These positive ions and negative ions adhere to objects such as suspended microorganisms and cause a chemical reaction on the surface. By this chemical reaction, active species hydrogen peroxide (H ₂ O ₂ ) and / or hydroxyl radical (· OH) are generated. These active species destroy the tissue of suspended microorganisms. This kills (removes in the case of viruses) suspended microbes.

  The charged particle generation units 41 to 44 are installed at the blowout ports 11 to 14 independent of each other. In addition, each of the charged particle generation units 41 to 44 can operate only one of the electrode portion 413 generating positive ions and the electrode portion 412 generating negative ions. Therefore, any one of the air containing positive ions and the air containing negative ions can be blown out from each of the blowout ports 11-14. Thereby, it is possible to prevent that the positive ions and the negative ions in the air blown out from the charged particle generation device 100 are electrically neutralized immediately. Therefore, it becomes possible to diffuse charged particles more widely.

  In order to increase the amount of charged particles delivered to the environment, the voltage applied to the electrode portions 413 and 412 may be increased. Alternatively, the number of times of voltage application may be increased by shortening the period of applying the voltage to the electrode portions 413 and 412. As a result, the amount of charged particles generated increases, and the amount of charged particles delivered can be increased. In general, the amount of charged particles can be easily increased by increasing the amount of air passing through the electrode portions 413 and 412.

  FIG. 6 is a plan view showing an example of the internal configuration of the charged particle generation device 100 shown in FIG. FIG. 6 shows the panel 2 (see FIG. 2) removed. Referring to FIG. 6, a fan 3 is provided at the center of the charged particle generator 100. The fan 3 is a so-called turbo fan, and includes a plurality of wing plates 30. The rotation direction of the fan 3, that is, the wing plate 30 is indicated by an arrow A.

  Each of the wing plates 30 is provided parallel to the rotation axis of the fan 3. In addition, each of the wing plates 30 is provided to be inclined with respect to the radial direction of the fan 3. That is, the distances from the rotation axis of the fan 3 to the left and right ends of each slat 30 in the radial direction are different from each other. As the fan 3 rotates, air is taken in from the inlet 10 (see FIG. 2). The introduced air is delivered radially outward of the fan 3 by the wing plate 30. The air is blown out from the blowout ports 11 to 14 in the state of containing the charged particles.

  The longitudinal dimension of the outlets 11 to 14 is longer than the distance between the electrode portion 412 and the electrode portion 413. Suppression members 61 to 64 are respectively provided inside the blowout ports 11 to 14 between the electrode portion 412 and the electrode portion 413 along the longitudinal direction of the blowout ports 11 to 14. The suppression members 61 to 64 function as an air flow rate adjustment unit for equalizing the air flow rate at the electrode portion 412 and the air flow rate at the electrode portion 413. In the following, the suppression member 64 provided in the blowout port 14 will be representatively described. The configuration of the other suppression members 61 to 63 is the same as the configuration of the suppression member 64.

  FIG. 7 is a plan view showing the blowout port 14 shown in FIG. 6 in an enlarged manner. FIG. 8 is a cross-sectional view schematically showing a cross section of the outlet 14 taken along line VIII-VIII shown in FIG. FIG. 9 is a cross-sectional view schematically showing the cross section of the air outlet 14 along the line IX-IX shown in FIG. With reference to FIGS. 8 and 9, the wing plate 30 is hatched for convenience for distinction from the other portions.

  7-9, the inside of the blower outlet 14 has a substantially rectangular parallelepiped space, and one surface of the substantially rectangular parallelepiped is the blower outlet 14. At the other surface intersecting the one surface, an inlet 74 communicating with the outlet 14 is provided. The air flowing in from the inlet 74 is blown out from the outlet 14 through the inside of the outlet 14. The remaining surface of the substantially rectangular parallelepiped is constituted by a member such as the case 1 and air does not flow into the environment except for the blowout port 14. The length of the inlet 74 is substantially the same as the length of the outlet 14, and the height of the inlet 74 is substantially the same as the height of the blade 30 of the fan 3.

The suppressing member 64 is, for example, a rectangular plate-like body. The width of the suppression member 64 is smaller than the dimension in the lateral direction of the outlet 14. Further, the height of the suppression member 64 is smaller than the height of the wing plate 30 of the fan 3. The suppressing members 61 to 64 are provided in contact with the side surface of the case 1 and at an appropriate distance from the rotation path of the wing plate 30.

  The air (represented by an arrow B in FIG. 7) delivered from the fan 3 flows into the inlet 74 and passes through the inside of the outlet 14 and is blown out from the outlet. The fan 3 causes air to flow into the inlet 74 along the direction from the electrode portion 413 toward the electrode portion 412. Therefore, when the suppression member 64 is not provided, the amount of air at the electrode portion 412 is larger than the amount of air at the electrode portion 413.

  The suppressing member 64 blocks a part of the air flowing in from the introduction port 74 to suppress the air flow to the electrode portion 412 (represented by an arrow D in FIG. 7). The air whose flow toward the electrode portion 412 is suppressed flows toward the electrode portion 413 (represented by an arrow C in FIG. 7). Thus, the air volume at the electrode portion 412 is reduced, and the air volume at the electrode portion 413 is increased. Therefore, by using the suppressing member 64 having an appropriate dimension, the air volume at the electrode portion 413 generating positive ions and the air volume at the electrode portion 412 generating negative ions can be made equal. As a result, the balance between the amount of positive ions delivered from the outlet 14 and the amount of negative ions delivered can be improved.

  In the above description, the dimension (area or suppression range) of the suppression member 64 is fixed. However, the dimensions of the suppression member 64 may be changeable.

  FIG. 10 is a cross-sectional view showing another example of the configuration of the air outlet 14 shown in FIG. Referring to FIG. 10, the configuration of outlet 14 shown in FIG. 10 is shown in FIG. 9 in that the suppression member is movable, and that fan rotation number detection unit 51 and height change unit 52 are provided. It differs from the configuration of the air outlet 14. The other configuration shown in FIG. 10 is the same as the configuration shown in FIG. 9, and thus the detailed description will not be repeated.

  The fan rotation number detection unit 51 detects the rotation number of the fan 3. Instead of the rotational speed of the fan 3, the air volume by the fan 3 may be detected. That is, the air volume by the fan 3 may be directly detected, or the air volume by the fan 3 may be indirectly detected by detecting the rotational speed of the fan 3 having a correlation with the air volume.

  The height changing unit 52 changes the height of the suppression member in accordance with the air volume detected by the fan rotation number detection unit 51 (or the rotation number of the fan 3). The suppression member is constituted of, for example, two plate-like members 641 and 642. The plate member 642 is fixed to the case 1. The plate member 641 can move along the joint member 643. Thereby, the height as the whole control member can be changed.

  When the rotational speed of the fan 3 is a certain value, it is assumed that the air volume at the electrode portion 412 and the air volume at the electrode portion 413 are equal. If the air flow rate is increased by increasing the rotational speed of the fan 3 from this state, the air flow rate at the electrode portion 413 becomes larger than the air flow rate at the electrode portion 412 by the suppression member. Therefore, the height of the suppressing member is lowered. As a result, air easily flows toward the electrode portion 412, so the air volume at the electrode portion 412 and the air volume at the electrode portion 413 become equal. Conversely, when the air flow rate is reduced by lowering the rotational speed of the fan 3, the air flow rate at the electrode portion 413 becomes smaller than the air flow rate at the electrode portion 412. Therefore, the height of the suppression member is increased. As a result, the air volume at the electrode portion 413 is increased, so the air volume at the electrode portion 412 and the air volume at the electrode portion 413 become equal.

As described above, even when the number of rotations or the air volume of the fan 3 is changed by making the dimension of the suppression member changeable, the air volume at the electrode portion 412 and the air volume at the electrode portion 413 are equal. can do. In the configuration shown in FIG. 10, the height of the suppressing member can be changed. However, the method of changing the dimension of the suppression member is not limited to this.

  Next, the microorganism detection device 500 in the air conditioning system 200 according to the embodiment of the present invention will be described. FIG. 11 is a flowchart for explaining the microorganism detection process performed by the microorganism detection device 500 in the air conditioning system 200 shown in FIG. 1. Referring to FIG. 11, the microorganism detection apparatus 500 is configured to detect a microorganism through steps roughly classified into three stages. The first step is the collection step shown in steps S101, S102 and FIG. The process of the second stage is the fluorescence measurement process (before and after heating) shown in steps S103 to S108, FIG. 13 and FIG. The process of the third stage is the refresh process shown in steps S109 and S110 and FIG.

  FIG. 12 is a schematic view for explaining the principle of the collecting step in the flow chart shown in FIG. FIG. 13 is a schematic view for explaining the principle of the pre-heating fluorescence measurement step in the flowchart shown in FIG. FIG. 14 is a schematic view for explaining the principle of the after-heating fluorescence measurement step in the flowchart shown in FIG. FIG. 15 is a schematic diagram for explaining the principle of the refresh process in the flow chart shown in FIG.

  With reference to FIGS. 12-15, the main-body part of the microorganisms detection apparatus 500 is a substantially rectangular parallelepiped, and is about 5 cm long x 6 cm wide x 3 cm high. The microorganism detection apparatus 500 includes a table (collection unit) 510, a heater 520, a discharge electrode 530, a voltage device 540, a light source 550, a lens 560, a light reception unit (detection unit) 565, and a fan 570. A brush (refresh unit) 580 and a rotating device (not shown) are provided. The rotation device rotates the table 510 around the rotation center (eg, the right end of the table 510). Thus, the table 510 is configured to sequentially pass through the steps shown in the flowchart of FIG.

  First, referring to FIGS. 11 and 12, in the collection step, microorganism detection apparatus 500 collects microorganism 600A suspended in the air. At this time, chemical fibers 600B suspended in the air are also collected together (step S101). More specifically, the table 510 is a mirror-finished glass disc. The discharge electrode 530 is a needle-like electrode, and its tip end faces the table 510. The voltage supplied from the voltage device 540 causes the discharge electrode 530 to form an electric field between the table 510 and the discharge electrode 530. Thereby, the float 600 (microorganisms 600A and chemical fiber 600B) is charged. The charged float 600 is adsorbed and collected on the surface of the table 510 maintained at the reference potential. In step S102, the rotation device moves the table 510 to a position for measuring the fluorescence intensity.

  Next, referring to FIGS. 11 and 13, in the pre-heating fluorescence measurement step, light source 550 emits excitation light such as ultraviolet light toward collected suspended matter 600. Thus, the microorganism 600A and the chemical fiber 600B emit fluorescence specific to the components in the respective substances. The lens 560 collects the fluorescence from the float 600. The light receiving unit 565 receives the fluorescence collected by the lens 560. The fluorescence received by the light receiving unit 565 is analyzed by an analysis unit (not shown) (step S103). The surface of the table 510 is mirror-finished in order to prevent generation of unnecessary scattered light in the process of step S103. The table 510 which has finished the pre-heating fluorescence measurement is temporarily removed from the position for measuring the fluorescence, and returns to the collection position in step S101 (step S104).

The heater 520 heats the floating matter 600 collected on the table 510 together with the table 510 (step S105). Thereafter, the fan 570 cools the table 510. (Step S106). In step S107, the rotation device moves the table 510 to the position for measuring the fluorescence intensity again. Referring to FIGS. 11 and 14, in the post-heating fluorescence measurement step, as in the pre-heating fluorescence measurement step, the microorganism 600A and the chemical fiber 600B are irradiated with excitation light again to analyze fluorescence (step S108). .

  By simultaneously heat treating the microorganism 600A and the chemical fiber 600B in step S105, the microorganism 600A is killed and the chemical fiber 600B changes in molecular state. For this reason, a change occurs in fluorescence before and after heat treatment. Therefore, the amount of microorganisms 600A (for example, the number of microorganisms per unit volume) can be quantitatively evaluated by comparing the fluorescence measurement results before and after the heat treatment.

  Finally, referring to FIGS. 11 and 15, in the refresh step, brush 580 cleans float 600 on table 510 (step S109). The rotating device returns the table 510 to the collection position (step S110).

  The microorganism detection apparatus 500 does not utilize an antibody reaction between a microorganism and a specific antibody. Therefore, microorganisms can be detected regardless of their types. Also, no reaction time is required to detect microorganisms. Furthermore, once detection is complete, it can be initialized immediately by the refresh process. Therefore, the microorganism detection device 500 can repeat the process in steps S101 to S110. That is, the microorganism detection apparatus 500 can detect microorganisms continuously.

  FIG. 16 is a flowchart for explaining control of the control device 204 shown in FIG. Referring to FIGS. 1 and 16, in control device 204, temperature T1 (first temperature, for example, 15 ° C.) is set as the set temperature of air conditioner 202 in the stopped state (“stop mode”) of charged particle generation device 100. And a temperature T2 (a second temperature, for example, 17.degree. C.) higher than the temperature T1. The state where power is supplied to the air conditioning system 200 is a start. In the present embodiment, the amount of charged particles delivered (ie, zero) in the stopped state of charged particle generator 100 corresponds to the “first amount of delivery” according to the present invention, and the operation of charged particle generator 100 is performed. The amount of charged particles delivered at a time corresponds to the “second amount delivered” according to the present invention.

  In step S201, the control device 204 acquires information on the operation mode of the charged particle generation device 100 (the above four operation modes or the stopped state of the charged particle generation device 100). If the charged particle generation device 100 is in operation, the process proceeds to step S203 (YES in step S202). In step S203, the control device 204 sets the set temperature of the air conditioner 202 to the temperature T2. On the other hand, when the charged particle generation device 100 is stopped, the process proceeds to step S204 (NO in step S202). In step S204, the control device 204 sets the set temperature of the air conditioner 202 to the temperature T1.

  In step S205, the microorganism detection apparatus 500 detects the amount of microorganisms around the food processing facility 203. The controller 204 acquires this detection result.

  In step S206, the control device 204 compares the detection result of the microorganism detection device 500 with a predetermined reference value (for example, a reference value defined by the Food Sanitation Act or a value stricter than that). If the detection result exceeds the reference value, the process proceeds to step S207 (YES in step S206). On the other hand, if the detection result is less than or equal to the reference value, the process proceeds to step S212 (NO in step S206).

In step S207, (a) immediately after the power is turned on to the air conditioning system 200, or (b) it is sudden that the detection result by the microorganism detection device 500 exceeds the reference value. Or (c) it is determined whether the detection result exceeds the reference value despite the fact that the amount of charged particles delivered by the charged particle generator 100 is maximum (the operation mode of the charged particle generator 100 is “rapid mode”) . If at least one of (a) to (c) is applicable, the process proceeds to step S210 (YES in step S207). On the other hand, if none of (a) to (c) is true, the process proceeds to step S208 (NO in step S207).

  In step S208, the control device 204 controls the charged particle generation device 100 to increase the amount of charged particles delivered into the environment more than before the detection result exceeds the reference value. The operation mode of charged particle generator 100 is set to, for example, "full power mode" or "rapid mode". Moreover, in step S209, the control device 204 sets the set temperature of the air conditioner 202 to the temperature T2.

  In conventional air conditioning systems, the activity of microorganisms is suppressed by lowering the temperature in the environment to a temperature T1. On the other hand, according to the air conditioning system 200 according to the embodiment of the present invention, microorganisms are sterilized and reduced by increasing the amount of charged particles delivered. Therefore, even if the temperature in the environment is a temperature T2 higher than the temperature T1, the amount of microorganisms in the environment does not increase. Therefore, as in the conventional air conditioning system, for example, a hygienic environment suitable for food processing can be realized.

  Further, the power saved by replacing the set temperature of the air conditioner 202 with the temperature T1 and setting the temperature to T2 is larger than the increase in the power consumption of the charged particle generator 100. Therefore, the power consumption of the air conditioning system 200 as a whole can be reduced. Furthermore, as mentioned above, the physical burden is heavy for workers working in a low temperature environment. According to the air conditioning system 200, it is possible to suppress overcooling and reduce the physical load on the worker. That is, a healthier working environment can be realized.

  Next, in steps S210 and S211, the control device 204 gives priority to restoring the hygienic environment. The control device 204 controls the charged particle generation device 100 so that the generation amount of charged particles is maximized (step S210), and sets the set temperature of the air conditioner 202 to the temperature T1 (step S211). Thereby, in addition to suppressing the activity of the microorganism by lowering the temperature in the environment, the microorganism can be reduced by the charged particles having the maximum amount of generation. In addition, the conditions of said (a)-(c) are the illustrations of the conditions which give priority to restoring a hygienic environment, Comprising: It is not limited to these.

  Conversely, in steps S212 and S213, the control device 204 gives priority to reducing the power consumption of the air conditioning system 200. In step S213, the control device 204 controls the charged particle generation device 100 to reduce the amount of charged particles delivered to the environment more than before the detection result exceeds the reference value. When the charged particle generation device 100 is in operation, the operation mode of the charged particle generation device 100 is set to, for example, the “standard mode” or the “weak mode”. Alternatively, the charged particle generator 100 can be stopped. If the charged particle generation device 100 has already been stopped, the state is maintained. Further, in step S212, the control device 204 sets the set temperature of the air conditioner 202 to the temperature T2.

  Even after that, the control device 204 controls the charged particle generation device 100 so as to reduce the amount of charged particles delivered as long as the detection result by the microorganism detection device 500 can maintain the state below the reference value. Thereby, the power consumption of the air conditioner 202 can be reduced as in the processes in steps S208 and S209. Further, power consumption of the charged particle generation device 100 can be reduced more than the processing in steps S208 and S209.

When the process in any one of steps S209, S211, and S213 is completed, the process returns to step S201 again. The order of the process in step S208 and the process in step S209 may be interchanged. Similarly, the order may be switched between the process in step S210 and the process in step S211, and between the process in step S212 and the process in S213.

  In the above description, the temperature T1 is determined as the set temperature in the stop state of the air conditioner 202. However, the method of determining the set temperature is not limited to this. For example, the set temperature corresponding to the “weak mode” of the charged particle generation device 100 may be taken as the temperature T1.

  According to a verification test conducted by the inventors, the temperature in the working environment in the factory has conventionally been 15 ° C. According to the air conditioning system according to the embodiment of the present invention, even when the temperature is raised to 17 ° C., the detected amount of microorganisms is equal. Therefore, it has been demonstrated that a hygienic environment meeting the Hygiene and Environmental Approach (HACCP) standard is maintained. In addition, power consumption could be reduced by about 20% from the viewpoint of power saving. Furthermore, from the viewpoint of the physical load of workers, the Industrial Hygiene Law sets the environmental temperature standard at 17 ° C. to 28 ° C. in the case of an office. It is said that there is no problem at 18 ° C to 24 ° C in the workplace. Taking these into consideration, it can be said that the ability to raise the temperature in the working environment from 15 ° C. to 17 ° C. is significant from the viewpoint of the physical load of the worker.

  By the way, the country has formulated a plan for food processors in the area affected by the Great East Japan Earthquake, and “The high-level sanitation management in this plan refers to each process from landing to handling and shipping of marine products to be handled Implement comprehensive measures of hardware and software for analyzing, identifying, and removing biological, chemical or physical hazards, and conduct regular surveys and inspections to ensure the sustainability of this initiative By managing records, we aim to establish a system that enables provision of such information in response to a request from a consumer etc. ”. The present invention realizes these plans and also enables energy saving.

  The charged particle generator 100 has been described as generating both positive ions and negative ions. However, the same effect can be obtained even if the charged particle generator has a configuration other than the above. For example, in the charged particle generation apparatus, a combination of a positive ion generation apparatus and a liquid atomization apparatus for generating charged fine water droplets of negative polarity can be used. A combination of an electrolyzed water spray device for spraying electrolyzed water obtained by electrolyzing water and a discharge device may be used.

  In addition, it has been described that the control device 204 controls the air conditioner 202 and the charged particle generation device 100 based on the detection result of the microorganism detection device 500. However, the air conditioner 202 and the charged particle generation device 100 may directly obtain the detection result from the microorganism detection device 500. In addition, the air conditioner 202 may directly receive information on the operation mode of the charged particle generation device 100 from the charged particle generation device 100. In this case, based on the detection result of the charged particle generation device 100 and the operation mode of the charged particle generation device 100, the air conditioner 202 itself sets the set temperature to the temperatures T1 and T2.

  Furthermore, in FIG. 1, it has been described that the microorganism detection device 500 is installed on the wall surface of the factory building 201. However, as described with reference to FIGS. 11 to 15, the configuration of the microorganism detection device 500 is simple. Therefore, the microorganism detection device 500 is easy to handle and can be miniaturized. Therefore, the microorganism detection device 500 can also be provided, for example, inside the air conditioner. The air conditioning system according to the present invention can also be mounted on, for example, a vehicle.

Embodiments of the present invention can be summarized as follows.
The air conditioner 202 controls the temperature in the environment to a set temperature, and the charged particle generator 100 generates charged particles by discharging to send charged particles into the environment, and the amount of charged particles is 1 The temperature T1 is determined as the set temperature of the air conditioner 202 in the case of the amount of delivery of the air conditioner, and the set temperature is higher than the temperature T1 when the amount of the charged particles delivered is the second delivery amount larger than the first delivery amount. Air conditioning system 200, which also sets high temperature T2.

  According to the above configuration, it is possible to realize a hygienic environment and to raise the temperature in the environment by the sterilizing effect of the charged particles generated by the charged particle generation device 100. As a result, the power consumption of the air conditioning system 200 can be reduced.

  An air conditioning system 200, which determines a temperature T1 as a set temperature of the air conditioner 202 in a stop state of the charged particle generation device 100.

According to the above configuration, the power consumption of the air conditioning system 200 can be further reduced.
The apparatus further comprises a microorganism detection apparatus 500 for detecting the amount of microorganisms in the environment, and the charged particle generation apparatus 100 acquires the detection result by the microorganism detection apparatus, and when the detection result exceeds a predetermined reference value, the environment An air conditioning system 200 that increases the amount of charged particles delivered into the inside, before the detection result exceeds a reference value.

According to the said structure, the microorganisms in an environment can be disinfected more rapidly.
The air conditioning system 200 which sets the preset temperature of the air conditioner 202 to the temperature T1 when the detection result by the microorganism detection device 500 exceeds a reference value.

According to the above configuration, the activity of the microorganism in the environment can be suppressed more rapidly.
The control device 204 further controls the air conditioner 202 and the charged particle generation device 100. The control device 204 controls the air conditioner 202 and the charged particle generation device 100 based on the detection result of the microorganism detection device 500. Air conditioning, adjusting at least one of a set temperature of the air conditioner 202 and a delivery amount of charged particles delivered from the charged particle generation device 100 so that a state in which the detection result becomes less than a reference value is maintained. System 200.

  According to the above configuration, it is possible to appropriately control the air conditioner 202 and the charged particle generation device 100 according to the hygienic state in the environment based on the detection result indicating the amount of microorganisms.

  The microorganism detection device 500 includes an air conditioning system including a table 510 for collecting microorganisms, a light receiving unit 565 for detecting the collected microorganisms, and a brush 580 for returning the table 510 to a state before collecting microorganisms. 200.

  According to the above configuration, the microorganism detection apparatus 500 can repeatedly detect the microorganism by sequentially performing the process by each component.

  In an air conditioning method of an air conditioning system 200, the air conditioning system 200 generates charged particles by discharging an air conditioner 202 that adjusts the temperature in the environment to a set temperature, and discharges charged particles into the environment. The air conditioning method comprises the steps of: setting the set temperature of the air conditioner 202 at a temperature T1 when the amount of charged particles delivered from the charged particle generator 100 is a first amount of delivery; In S204, when the amount of charged particles delivered from the charged particle generator 100 is a second amount of delivery larger than the first amount of delivery, the set temperature of the air conditioner 202 is set to a temperature T2 higher than the temperature T1. An air conditioning method comprising the step of defining S203.

According to the above method, a hygienic environment can be realized and the temperature in the environment can be raised by the sterilizing effect of the charged particles generated by the charged particle generation device. As a result, the power consumption of the air conditioning system 200 can be reduced.

  The temperature T1 is a set temperature of the air conditioner 202 in the stop state of the charged particle generation device 100.

According to the above method, the power consumption of the air conditioning system 200 can be further reduced.
The air conditioning system 200 further includes a microorganism detection device 500 for detecting the amount of microorganisms in the environment, and when the detection result by the microorganism detection device 500 exceeds a predetermined reference value, delivery of charged particles to the environment is performed. The air conditioning method further comprising steps S208 and S210 of increasing the amount more than before the detection result exceeds the reference value.

According to the above method, microorganisms in the environment can be more rapidly sterilized.
The air conditioning method further includes a step S211 in which the set temperature is set to a temperature T1 when the detection result by the microorganism detection device exceeds a reference value.

According to the above method, the activity of microorganisms in the environment can be suppressed more rapidly.
It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is indicated not by the above description but by the claims, and is intended to include all modifications within the meaning and scope equivalent to the claims.

200 air conditioning system, 201 factory building, 201R ceiling, 201D door, 202 air conditioner, 203 food processing equipment, 204 control device, 100 charged particle generator, 500 microorganism detection device, 1 case, 2 panels, 3,570 fans , 30 blades, 10 inlets, 11 to 14 outlets, 21 to 24 louvers, 25 display panels, 41 to 44 charged particle generation units, 411 storage units, 411a charged particle generation units, 412, 413 electrode units, 414 charges Particle sensor 415 connector 416 screw 51 fan rotation number detector 510 table 520 heater 530 discharge electrode 540 voltage device 550 light source 560 lens 565 light receiver 580 brush 600 floats 600A microorganism , 600 B chemical fiber, 61 to 64 suppressing member, 641, 64 2
Plate member, 643 joint member, 74 inlet.

Claims (2)

An air conditioner that regulates the temperature in the environment to the set temperature,
A charged particle generator for generating charged particles by discharge and delivering the charged particles into the environment;
The charged particles include positive ions and negative ions generated by ionizing water vapor in air by plasma discharge,
The positive ion is H ⁺ (H ₂ O) _n , where n is an arbitrary natural number,
The negative ion is O ₂ ⁻ (H ₂ O) _m , where m is an arbitrary natural number,
While cooling by the air conditioner, the first temperature is determined as the set temperature of the air conditioner when the discharge amount of the charged particles is the first discharge amount, and the discharge amount of the charged particles is the discharge amount of the charged particles. An air conditioning system for food processing , wherein the set temperature is set to a second temperature higher than the first temperature when the second discharge amount is larger than the first discharge amount. The air conditioning system for food processing according to claim 1, wherein the first temperature is determined as the set temperature of the air conditioner in a stopped state of the charged particle generator.

Images