JP4278751B2 - Steam recovery device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control method in a steam recovery apparatus in the field of air conditioning technology that is used for efficiently recovering steam emitted from a cooking / shower room or the like and prevents condensation on the ceiling or wall surface of the room.
[0002]
[Prior art]
Conventionally, an apparatus for collecting this kind of water vapor generally uses a ventilation fan or a range hood, and takes a method of discharging water vapor generated indoors to the outside or another space. Further, as a ventilation system for preventing the generation of mold by removing and discharging water vapor generated in the room, the indoor ventilation fan as shown in Japanese Patent Laid-Open No. 06-147583 is operated and controlled, and the ventilation fan and the range hood In general, a method of discharging water vapor generated in a room is common. The configuration will be described below with reference to FIG.
[0003]
As shown in FIG. 16, a fan motor 101 is provided above or on a wall surface of a cooking table that generates water vapor in the room so as to discharge water vapor generated from cooking or water vapor generated in the room, and a casing that surrounds the fan motor 101. A hood 102 is provided.
[0004]
In the above configuration, the fan motor 101 is operated, and steam from the steam generator 103 such as cooking is forcibly sucked into the hood 102 and discharged outside the room.
[0005]
Further, although not shown in the figure, the water vapor generated in the shower room / bathroom or the like similarly operates the fan motor 101 to discharge the water vapor generated from the room to the outside.
[0006]
[Problems to be solved by the invention]
In such a conventional apparatus for discharging water vapor, it is difficult to recognize the generation of steam and it is necessary to continuously operate the apparatus. Therefore, the apparatus is continuously energized to consume a lot of power and exhaust indoor air. Therefore, there is a problem of increasing the energy required for indoor air conditioning, and it is required to operate simultaneously with the generation of water vapor to reduce the power consumption of the device and reduce the energy required for indoor air conditioning. .
[0007]
In addition, when the position of the circuit for recognizing the generation of water vapor is on the leeward side, there is a problem that the time for recognizing water vapor is delayed because the inflow path of water vapor is longer than that on the windward side, and the time for collecting water vapor is delayed. Is required to recover the water vapor reliably.
[0008]
Further, the location where water vapor is generated from the heater raises the humidity of the entire work chamber in order to evaporate a large amount of water. However, the cold air from the refrigerator or freezer generates water vapor in one part of the room due to the cooling effect and does not raise the humidity of the whole room, so there is a problem that it is difficult to recognize by humidity, and steam is efficient without being affected by humidity There is a demand for good recovery.
[0009]
In addition, processing equipment that produces boiled foods and smoked foods from food factories, etc., continuously produces processed foods, so there is a problem that processing processes cannot be stopped except for regular repairs. Therefore, it is required that maintenance parts can be reduced and repairs can be easily performed.
[0010]
In addition, places that produce boiled foods and smoked products in large quantities have an unmanned processing process, and there is a problem that humans cannot recognize the generation of steam and cannot operate a device that collects water vapor. Recognizing that steam is required to be recovered.
[0011]
In addition, since the generation of water vapor differs depending on the source and the temperature and humidity of the atmosphere, such as cold air in refrigerators and freezers, and hot air such as cooking in kettles, there is a problem that it is difficult to recognize water vapor, and it can be seen by the actual person It is required to remove water vapor.
[0012]
Further, the generated water vapor has a problem of diffusing into the atmosphere and increasing the humidity in a dry atmosphere, and prevents any water vapor from being diffused in any atmosphere and can collect a large amount of water vapor. It is requested.
[0013]
Also, a place where a large amount of water vapor is generated has a problem of increasing the capacity of the apparatus in order to catch up with the amount of water vapor generated, and there is a demand for efficiently recovering a large amount of water vapor with the same capacity.
[0014]
In addition, the water vapor of the boiled food cooking and the water vapor of the shower in the food factory is considerably higher than the temperature in the atmosphere, and suddenly generates water vapor, so even if a means for recognizing water vapor in the device is provided, There is a problem that the generated amount cannot be processed, and there is a demand for control of a steam recovery apparatus that recognizes the generation of steam in advance.
[0015]
In addition, steam generated during cooking in food factories, for example, increases the pressure in the container of the source due to heating and suddenly generates water vapor. Therefore, there is a problem that it cannot be recognized, and there is a demand for control of a steam recovery apparatus that recognizes the generation of steam in advance.
[0016]
In addition, steam and hot water for cooking in a food factory are heated in a closed container by a pot or pan, and when the lid of the pot or pan is opened, water vapor is suddenly generated. Even if a means is provided, there is a problem that the generation cannot be recognized and the water vapor cannot be processed, and it is desired to recognize the generation of water vapor and to easily recognize the generation of water vapor.
[0017]
Also, boiled food cooking and hot water making in food factories are made up of many devices through automation, so adding a means for recognizing water vapor to each device increases the cost of the device. There is a problem, and it is desired to recognize water vapor easily even in many water vapor generators.
[0018]
In addition, when the generated water vapor is higher than the ambient temperature, there is a tendency that an upward air flow is created and the water vapor tends to rise upward, but there are many things that diffuse into the atmosphere, so there is a problem that it does not flow into the apparatus that collects the water vapor. It is required to attract and collect water vapor in an apparatus for collecting water vapor.
[0019]
In addition, the amount of water vapor generated varies depending on the atmospheric humidity, and there is a problem that the amount of water vapor decreases before entering the water vapor recovery device, and there is a demand for being not affected by the atmospheric temperature.
[0020]
[Means for Solving the Problems]
The present invention solves such a conventional problem, can be operated simultaneously with the generation of water vapor, can reduce power consumption, can ensure steam recognition early, Water vapor can be efficiently recovered without being affected by humidity, maintenance parts can be reduced and repairs can be easily performed, and steam can be automatically recognized and recovered. It can remove water vapor that can be seen by human eyes, can prevent the diffusion of water vapor in any atmosphere, can collect a large amount of water vapor, and can collect a large amount of water vapor with the same capacity. In addition, it is possible to control a steam recovery device that recognizes the generation of water vapor, and to control a steam recovery device that recognizes the generation of water vapor, and to recognize the generation of water vapor. In addition, it is possible to easily recognize the generation of water vapor in advance, and it is also possible to easily recognize water vapor even with a plurality of water vapor generation devices, making it cheaper, and attracting it to the device that collects water vapor. It is an object of the present invention to provide a water vapor recovery device that can be recovered and that is not affected by the ambient temperature.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates to a water vapor recovery device that condenses and condenses water vapor, and collects the condensed water vapor. Detecting the pressure in the device that generates the water vapor A water vapor recovery device is provided with a pressure sensor, and the operation of the water vapor recovery device is controlled by detection of the pressure sensor. Before the steam is generated, the pressure sensor senses the operation of the water vapor recovery device. Therefore, even if water vapor is suddenly generated, it is possible to accurately know the state in which the water vapor is generated in advance, and a large amount of water vapor that is suddenly generated can be drawn into the water vapor recovery apparatus.
[0035]
Embodiments of the present invention will be described below with reference to the drawings.
In addition, the same code | symbol is attached | subjected to the same location as a prior art example, and the detailed description is abbreviate | omitted.
[0036]
【Example】
( reference Example 1)
As shown in FIG. 1, the water vapor recovery apparatus 1 includes a discharge wire 2 that is a metal discharge means, a metal grid-like protective net 3 as an aggregation means that agglomerates the water vapor so as to sandwich the discharge wire 2, and A fan motor 101 which is a blowing means for passing air containing water vapor through the discharge wire 2 and the protective net 3, a humidity sensor 4 which detects the humidity of the water vapor on the windward side of the protective net 3, and a water receiving plate for storing the collected water droplets 5, a drain pipe 6 that discharges water droplets collected on the water receiving plate 5, a power unit 7 that supplies power to the discharge line, and an outer frame 102. The discharge wire 2 is made of tungsten, and has a wire diameter of 100 to 150 μm and plated with gold. The protective net 3 is made of stainless steel with a wire diameter of 0.1 mm, and a lattice of 3 mm. Further, the discharge line 2 and the protective net 3 are 4 to 6 kV / cm from the power unit 7. ² The one that can supply the electric field is used.
[0037]
FIG. 2 shows the input of the humidity sensor 4, the energization status of the discharge wire 2, and the operating status of the fan motor 101.
[0038]
With the above configuration, the water vapor generated from the shower or cooking generates an ascending air current, is guided into the water vapor recovery device 1, passes through the vicinity of the humidity sensor 4, and the air containing the water vapor by the humidity sensor 4 has a humidity of 90% or more. When a direct current electricity is supplied from the power unit 7 to the discharge line 2 and the humidity sensor 4 generates a control signal for operating the fan motor 101 when the air containing water vapor is 90% or more of humidity. Take control. The water vapor is passed through the protective net 3 and the discharge wire 2 by the rising air flow and the fan motor 101, and the water vapor is charged in the corona discharge region in the discharge wire 2 and the protective net 3, and is adhered to the protective net 3. The water droplets fall into the water receiving plate 5 from the protective net 3 and drain through the drain pipe 6 to collect water vapor in the air.
[0039]
In addition, by recognizing the water vapor generated from the water vapor generator 103 and collecting the water vapor in the room, it prevents the water vapor from adhering to the wall surface of the room and prevents the growth of microorganisms that use the wall material and moisture as nutrients. , Falling bacteria and indoor floating microorganisms can be reduced.
[0040]
Further, since the humidity sensor 4 automatically operates the water vapor recovery apparatus 1, it is possible to eliminate the operation of stopping the apparatus and to easily manage the operation state of the apparatus.
[0041]
In addition, reference In the example, the linear discharge wire 2 is used as the discharging means, but a needle, a granular shape, or a lattice-shaped one such as a protective net may be used.
[0042]
Also, reference In the example, tungsten is used for the discharge wire 2, but instead of other metal or metal, non-conductive resin or ceramic coated with conductive resin, ceramic, fiber, conductive paint or the like. Even if fibers are used, there is no difference in their effects.
[0043]
Also, reference In the example, the discharge wire 2 having a wire diameter of 100 to 150 μm is used. However, if a wire wire having a wire diameter capable of discharging is used, there is no difference in its effect.
[0044]
Also, reference In the example, the grid-like protective net 3 is used as the aggregating means, but any means can be used as long as the electricity of the discharging means is energized, such as a plate, a plate with a needle attached, a granular shape, or a linear shape. .
[0045]
Also, reference In the example, the protective net 3 is made of stainless steel, but in place of other metal or metal, a conductive material or a non-conductive resin or ceramic coated with a conductive paint, etc. Even if fibers are used, there is no difference in their effects.
[0046]
Also, reference In the example, the protective net 3 having a wire diameter of 0.1 mm is used. However, if a wire diameter that forms a corona discharge region between the protective wire 3 and the discharge wire 2 is used, there is no difference in the function and effect.
[0047]
Also, reference In the example, the one supplied with direct current electricity from the power unit 7 is used, but alternating current and high frequency electricity may be used as long as it is a power supply system capable of forming a corona discharge region between the discharge wire 2 and the protective net 3. .
[0048]
Also, reference In the example, the grid-like protective net 3 and the discharge line 2 are installed perpendicular to the wind direction, but they may be installed in parallel or surrounding the discharge line.
[0049]
Also, reference In the example, a metal grid-like protective net 3 was used. However, even if a metal film with a coating such as paint, photocatalyst, or plating, or a resin with a conductive paint or conductive film, the effect is different. Does not occur.
[0050]
Also, reference In the example, the water is drained from the drain pipe 6. However, even if the absorbent is installed and the drainage is removed, there is no difference in the effect.
[0051]
Also, reference In the example, the discharge line 2 and the protection net 3 are 4 to 6 kV / cm at the power unit 7. ² Although an electric field of 6 kV / cm was supplied ² The above electric field is supplied by short waves and pulses, and there is no difference in the effect.
[0052]
Moreover, although it was set as the water vapor | steam generate | occur | produced from the shower or cooking, if it is saturated water vapor | steam, it can be collect | recovered if it is saturated water vapor | steam.
[0053]
( reference Example 2)
In addition, reference The same parts as those in Example 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0054]
As shown in FIG. 3, the water vapor recovery apparatus 1 includes a dew condensation sensor 8 that detects dew condensation on the windward side of the protective net 3, and the dew condensation sensor 8 uses a thin film sensor that measures electrical conductivity.
[0055]
FIG. 4 shows the input of the dew condensation sensor 8, the energization status of the discharge wire 2, and the operating status of the fan motor 101.
[0056]
With the above configuration, water vapor generated from showering or cooking in a high humidity atmosphere generates an upward air flow, is guided into the water vapor recovery device 1, passes near the dew condensation sensor 8, and the air containing water vapor is the dew condensation sensor 8. When dew condensation occurs, direct current electricity is supplied to the discharge line 2 from the power unit 7, and a control signal for operating the fan motor 101 is generated and controlled to operate. The water vapor passes through the protective net 3 and the discharge wire 2 due to the rising air current and the air blown by the fan motor 101, is charged in the corona discharge region in the discharge wire 2 and the protective net 3, and aggregates and adheres to the protective net 3. Water droplets fall on the water receiving plate 5 from the protective net 3, and drain through the drain pipe 6 to collect water vapor in the air. The water vapor in the superheated steam atmosphere above the saturated water vapor or cooled 1 The water vapor recovery apparatus 1 can be operated even when sudden water vapor is generated regardless of the humidity in the room.
[0057]
In addition, reference In the example, a thin film sensor that measures electrical conductivity is used as the dew condensation sensor 8, but a measuring device that can determine surface dew condensation using a semiconductor or a photocatalyst may be used.
[0058]
( reference Example 3)
In addition, reference The same parts as those in Example 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0059]
As shown in FIG. 5, the water vapor recovery apparatus 1 includes a micro current unit 9 that causes a micro current to flow through the discharge wire 2 and the protection net 3 as an energization resistance detection unit that detects the potential of water vapor in the atmosphere.
[0060]
FIG. 6 shows the detection of a minute amount of current, the energization status of the discharge wire 2, and the operating status of the fan motor 101.
[0061]
With the above configuration, the water vapor generated from the shower or cooking generates a rising air current, is led into the water vapor recovery device 1, passes through the discharge wire 2 and the protective net 3, and the insulation resistance in the air is reduced by the water vapor when passing. , Current will flow easily. Since a small amount of constant discharge current is supplied to the discharge wire 2 and the protection net 3 from the minute current unit 9 in advance, when the insulation resistance decreases, that is, when water vapor is generated, a current equal to or greater than the constant discharge current flows to detect the generation of water vapor. After the detection, direct current electricity is supplied from the power unit 7 to the discharge line 2, and a control signal for operating the fan motor 101 is generated and controlled to operate. The water vapor is passed through the protective net 3 and the discharge wire 2 by the rising air flow and the fan motor 101, is charged in the corona discharge region in the discharge wire 2 and the protective net 3, and aggregates and adheres to the protective net 3. Water droplets fall on the water receiving plate 5 from the protective net 3 and drain through the drain pipe 6 to collect water vapor in the air.
[0062]
In addition, although the discharge power source and the detection power source are referred to separately as the minute current unit 9, actually, the current detection means can be provided by the same device.
[0063]
In addition, it is possible to control the size of the steam recovery device without attaching any attached parts, reducing the man-hours during production, reducing the material cost, making it inexpensive, and providing constant discharge even without the generation of steam. Since current flows through the discharge wire 2 and the protective net 3, ozone is generated by air discharge, and the inside of the steam recovery apparatus 1 or the vicinity of the steam recovery apparatus 1 can be sterilized.
[0064]
( reference Example 4)
In addition, reference The same parts as those in Example 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0065]
As shown in FIG. 7, the water vapor recovery apparatus 1 includes a permeability sensor 10 that detects the color of water vapor on the windward side of the protective net 3.
[0066]
With the above configuration, the water vapor rises and is guided into the water vapor recovery device 1 so that the front of the eye becomes white when a large amount of water vapor is actually generated. The air containing water vapor to such an extent that it becomes white passes through the permeability sensor 10, the permeability sensor 10 detects water vapor by the permeability, and direct current electricity is supplied to the discharge line 2 from the power unit 7, and the fan A control signal for operating the motor 101 is generated, and control for operating is performed. The water vapor is passed through the protective net 3 and the discharge wire 2 by the rising air current and the fan motor 101, is charged in the corona discharge region in the discharge wire 2 and the protective net 3, and is condensed and adhered to the protective net 3. Water droplets fall on the water receiving plate 5 from the protective net 3 and drain through the drain pipe 6 to collect water vapor in the air.
[0067]
In addition, it is possible to collect water vapor that can be seen by humans, and it is possible to secure an operator's field of view and create an environment in which work can be performed safely.
[0068]
( reference Example 5)
In addition, reference The same parts as those in Example 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0069]
As shown in FIG. 8, a cooling device 11 is provided as means for blowing cool air to air containing water vapor on the windward side of the water vapor recovery device 1.
[0070]
With the above configuration, water vapor is generated from the water vapor generating device 103, and the water vapor to be diffused in the air is cooled in front of the water vapor recovery device 1, thereby causing an agglomeration effect and preventing the water vapor from being diffused. Steam is generated and recovered, and steam generated from the steam generator is recovered more efficiently to prevent an increase in indoor humidity and keep the indoor humidity constant. Then, the operating state of the air conditioner in the work environment can be kept constant or wasteful operation, that is, startup due to an increase in humidity and an increase in energy consumption due to temperature and humidity fluctuations can be prevented, and energy consumption can be reduced.
[0071]
( reference Example 6)
In addition, reference The same parts as those in Example 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0072]
As shown in FIG. 9, the exhaust air passage is branched and the air passage 12 is provided as a means for sending the air just before the saturation in which the water vapor is collected to the air containing the water vapor on the windward side of the water vapor collecting apparatus 1.
[0073]
With the above configuration, water vapor is generated from the water vapor generating device 103, and the water just before saturation is blown out from the exhaust air passage 12 through the exhaust air passage 12 in order to diffuse the water vapor to the low humidity in the air in front of the water vapor collecting device 1. The atmosphere is kept under saturated water vapor to maintain the water vapor, preventing the diffusion of water vapor and recovering a large amount of water vapor, preventing the diffusion of water vapor that rises in the updraft, increasing the water vapor recovery efficiency, and introducing the inside of the equipment However, since moisture is not taken away by the air in the atmosphere, it can be reliably recovered, and further, the water vapor that has not been recovered can be recovered again, so that water vapor leaking from the water vapor recovery device 1 can be prevented.
[0074]
( reference Example 7)
As shown in FIG. 10, only the humidity sensor output installed in the steam generator 103 and the humidity sensor 4 output in the steam recovery apparatus 1 and the humidity sensor in the steam recovery apparatus 1 when the humidity sensor 4 of the steam generator 103 is provided. The output at the time, the energization of the discharge wire 2, and the operating status of the fan motor 101 are shown. The water vapor discharged from the water vapor generating device 103 diffuses into the atmosphere before entering the water vapor collecting device 1, and There is a delay of a few seconds before the humidity sensor 4 of the recovery device 1 detects it. Moreover, since water vapor | steam diffuses, the humidity in atmosphere is raised and the time for which the water vapor recovery apparatus 1 is energized is lengthened. However, by attaching the humidity sensor 4 to the water vapor generating device 103, the fan motor 101 is energized simultaneously with the generation of water vapor, and further, the electric power is supplied to the discharge wire 2 and the protection net 3, so that the fan motor 101 uses the inside of the water vapor collecting device 1. The water vapor is forcibly and quickly sucked in, and the rising air flow of the generated water vapor is added, so that the water vapor can be recovered in a short time.
[0075]
From the above configuration, it is possible to predict the sudden generation of water vapor in an automation factory, etc., so that the water vapor recovery device is not operated continuously, the efficiency of recovering the water vapor floating in the updraft is increased, and the water vapor is generated in a short time. Water vapor collected and flowing into the room atmosphere can be prevented.
[0076]
(Example 1 )
As shown in FIG. 11, the output of the pressure sensor for detecting the pressure in the steam generator 103 and the output of the humidity sensor 4 in the steam recovery apparatus 1 when the pressure sensor for detecting the pressure in the steam generator 103 is provided. The output when only the humidity sensor 4 is installed in the steam recovery apparatus 1, the energization of the discharge wire 2, and the operation status of the fan motor 101 are shown until the steam output from the steam generator 103 enters the steam recovery apparatus 1. Furthermore, it is diffused in the atmosphere, and there is a delay of several seconds from the generation of water vapor until the humidity sensor of the water vapor recovery apparatus 1 detects it. Moreover, since water vapor | steam spread | diffuses, the humidity in an indoor atmosphere will be raised and the time which the water vapor | steam collection | recovery apparatus 1 energizes will be lengthened. However, by attaching a pressure sensor to the water vapor generation device 103, forced exhaust by the fan occurs earlier, and when it overlaps with the rising air flow, it can be sucked into the water vapor recovery device that quickly recovers the water vapor and can be controlled to recover in a short time.
[0077]
With the above configuration, it is possible to predict the sudden generation of water vapor at an automation factory, etc., so that the water vapor recovery device is not operated continuously, and the recovery efficiency of the water vapor that rises with the rising airflow is further increased. Leakage can be prevented.
[0078]
( reference Example 8 )
As shown in FIG. 12, the output of the infrared sensor that can confirm whether the lid is opened or closed as the lid opening / closing detection means in the water vapor generating device 103, the output when only the humidity sensor 4 in the water vapor collecting device 1 is energized, the energization of the discharge line 2, and the fan motor 101 The water vapor emitted from the water vapor generator 103 is diffused into the atmosphere before entering the water vapor collector 1, and there is a delay of several seconds from the generation of water vapor until the humidity sensor 4 of the water vapor collector 1 detects. Moreover, since water vapor | steam spread | diffuses, the humidity in an indoor atmosphere will be raised and the time which energizes a water vapor | steam collection | recovery apparatus will be lengthened. However, by detecting the opening and closing of the lid of the steam generator 103 by the output of the infrared sensor, forced exhaust by the fan occurs earlier, and when it overlaps with the rising air current, it is sucked into the steam recovery device that quickly recovers the steam, and for a short time Can be recovered.
[0079]
With the above configuration, even if there are a plurality of devices that generate water vapor in an automation factory or the like, it is possible to detect the device that generates water vapor that has come below the water vapor recovery device at one location, and a plurality of devices are provided with sensors. It can be installed easily.
[0080]
In addition, reference In the example, an infrared sensor is used as an example, but if it is a means capable of detecting a similar output, for example, a push button switch is turned on and output when the lid is opened, or output by a sound when the lid is opened or closed. You may use it.
[0081]
( reference Example 9 )
In addition, the same code | symbol is attached | subjected to the same location as the reference example 1, and the detailed description is abbreviate | omitted.
[0082]
As shown in FIG. 13, an output in which the time for opening and closing the lid of the water vapor generating device 103 is controlled by a timer, an output when only the humidity sensor 4 in the water vapor collecting device 1 is energized, the electric current of the discharge wire 2, and the operating status of the fan motor 101. Furthermore, the output when the lid of the device opens and closes is shown.
[0083]
FIG. 14 shows a steam recovery apparatus 1 and an apparatus that generates steam in an automation factory. In an automation factory or the like, an apparatus that generates steam is placed below the steam recovery apparatus 1 for a certain period of time, and the steam is generated at certain time intervals. By the time the steam is generated by the generator 103 and enters the steam recovery apparatus 1, it diffuses into the atmosphere, and there is a delay of several seconds until the humidity sensor 4 in the steam recovery apparatus 1 detects it. Moreover, since water vapor | steam spread | diffuses, the humidity in an indoor atmosphere will be raised and the time which the water vapor | steam collection | recovery apparatus 1 energizes will be lengthened. However, when the generated device reads at a certain time and outputs it by a timer, forced exhaust by the fan motor 101 occurs earlier, and when it overlaps with the rising air current, it is sucked into the water vapor recovery device 1 that quickly recovers the water vapor, for a short time. Can be recovered.
[0084]
With the above configuration, even if there are a plurality of devices that generate water vapor in an automation factory or the like, it is possible to provide a sensor in each of a plurality of devices without detecting a device that generates water vapor that has come below the water vapor recovery device 1. And can be installed easily.
[0085]
(Reference example 10 )
In addition, the same code | symbol is attached | subjected to the same location as the reference example 1, and the detailed description is abbreviate | omitted.
[0086]
As shown in FIG. 15, there are provided means 13 for blowing air not containing water vapor collected on the windward side of the water vapor collecting apparatus 1 and an opening 14 for preventing water vapor from being diffused.
[0087]
With the above configuration, water vapor is generated from the water vapor generating device 103, and in front of the water vapor collecting device 1, the air that collects the water vapor from four directions is sent to the water vapor to be diffused in the air by the blower means 13, whereby the water vapor collecting device A tornado is generated in front of 1, and water vapor from the water vapor generator 103 is forcibly sucked into the water vapor recovery device 1. Of course, since saturated air is generated from the blowout opening 14, the water vapor from the water vapor generating device 103 is maintained, and the diffusion of water vapor is prevented and a large amount of water vapor is recovered.
[0088]
Furthermore, by extending the hood, the humidity in the room is kept constant, the operation of the air conditioner in the work environment is kept constant, energy consumption due to startup and fluctuations can be reduced, and diffused water vapor can be recovered. Since a large amount of water vapor is collected and is not affected by the outside wind, it is possible to prevent dust and microorganisms from being mixed from the outside wind.
[0089]
In addition, the amount of water vapor generated is increased, the attractive force is increased, diffusion is prevented, the recovery rate is increased with respect to the fan input, energy is saved, and the phenomenon of dust drifting in the rising air flow when water vapor is generated is prevented. It is possible to prevent dust from entering the apparatus in which contamination occurs or contamination of microorganisms.
[0090]
In addition, reference In the example, the air blowing means 13 is installed. However, even if air that has been diverted using a fan motor is used, there is no difference in its operational effect.
[0091]
【The invention's effect】
As is clear from the above embodiments, according to the present invention, it is possible to provide a water vapor recovery apparatus that is effective in preventing the adhesion of water vapor to the indoor wall surface, preventing the growth of microorganisms, and reducing falling bacteria.
[0092]
In addition, since the water vapor recovery apparatus is automatically operated, it is possible to provide a water vapor recovery apparatus that is effective in eliminating operation management without human being stopping the operation of the apparatus.
[0093]
In addition, it is possible to provide a water vapor recovery apparatus that can recognize water vapor even in air in a superheated steam atmosphere that is equal to or higher than saturated water vapor, and that can operate the apparatus even in a sudden occurrence.
[0094]
In addition, it is possible to control the water vapor recovery apparatus without the size and attached parts, to reduce the number of man-hours during manufacture, to reduce the material cost, and to provide a water vapor recovery apparatus that can be manufactured at low cost.
[0096]
In addition, it can recognize water vapor even in air in a low temperature atmosphere above saturated water vapor, can operate the device even in sudden occurrence, and provides an environment where workers can actually see and create an environment where they can work safely. A steam recovery apparatus can be provided.
[0097]
In addition, it is possible to provide a water vapor recovery apparatus that can recover more moisture in the air, reduce indoor humidity, and create a comfortable working environment.
[0098]
In addition, it is possible to provide a water vapor recovery apparatus that can recover a larger amount of moisture in the air, keep the indoor humidity constant, and reduce the air conditioning energy of the work environment.
[0099]
In addition, by predicting the sudden generation of water vapor at an automation factory, etc., the water vapor recovery device is not operated continuously, increasing the recovery efficiency of the water vapor rising by the updraft and preventing leakage to the indoor ceiling It is possible to provide a water vapor recovery apparatus having an effect that can be achieved.
[0100]
In addition, by predicting the sudden occurrence of water vapor at an automation factory, etc., the water vapor recovery device is not operated continuously, and the recovery efficiency of the water vapor that rises with the updraft is increased, and leakage to the indoor ceiling is prevented. An effective steam recovery apparatus that can be prevented can be provided.
[0101]
In addition, by predicting the sudden generation of water vapor in an automation factory, etc., the water vapor recovery device is not operated continuously, it is controlled easily, and there are many devices that generate water vapor. Easy installation and simple control of operation and shutdown makes it easy to install a device that generates water vapor, or it can be controlled at a single location, reducing the cost of installing equipment. A steam recovery apparatus can be provided.
[0102]
In addition, by predicting the sudden generation of water vapor in an automation factory, etc., the water vapor recovery device is not operated continuously, it is controlled easily, and there are many devices that generate water vapor. Since it can be easily installed and the control is simple in terms of time, it is possible to provide a steam recovery apparatus that can be controlled without incorporating a steam generating apparatus.
[0103]
In addition, it is possible to recover the diffused water vapor, recover a large amount of water vapor, and is not affected by the external wind, etc., so that it is possible to prevent the entry of dust and microorganisms from the external wind. Equipment can be provided.
[0104]
In addition, the amount of water vapor generated is increased, the attractive force is increased, diffusion is prevented, the recovery rate is increased with respect to the fan input to save energy, the phenomenon of dust flying in the rising air flow when water vapor is generated, and the water vapor Therefore, it is possible to provide a water vapor recovery apparatus that is effective in preventing dust from entering the apparatus in which the contamination occurs and preventing contamination or contamination of microorganisms.
[Brief description of the drawings]
FIG. 1 is a perspective view of a steam recovery apparatus of Reference Example 1.
[Fig.2] Output of the same humidity sensor, energization of discharge wire, fan motor operation status diagram
FIG. 3 is a perspective view of a steam recovery apparatus of Reference Example 2.
[Figure 4] Condensation sensor output, discharge line energization, fan motor operation status diagram
FIG. 5 is a perspective view of a steam recovery apparatus of Reference Example 3.
[Fig.6] Same trace current change, discharge line energization, fan motor operation status diagram
7 is a perspective view of a water vapor recovery apparatus of Reference Example 4. FIG.
FIG. 8 is a perspective view of a water vapor recovery apparatus of Reference Example 5.
FIG. 9 is a perspective view of a steam recovery apparatus of Reference Example 6.
FIG. 10 is a diagram showing the output of the humidity sensor in the water vapor generating apparatus of Reference Example 7, the humidity sensor output in the apparatus, the energization of the discharge line, and the operating status of the fan motor.
FIG. 11 is a diagram showing the output of the pressure sensor in the water vapor generating apparatus according to the first embodiment of the present invention, the output of the pressure sensor in the apparatus, the energization of the discharge wire, and the operating situation of the fan motor.
FIG. reference Example 8 IR sensor output, humidity sensor output, discharge line energization, fan motor operating status diagram
FIG. 13 reference Example 9 The output at a certain time, the output of the humidity sensor in the water vapor recovery device, the energization of the discharge wire, the operation status of the fan motor
FIG. 14 is a perspective view of the water vapor recovery device and a device for generating water vapor in an automation factory.
FIG. 15 Reference example 10 Perspective view of water vapor recovery equipment and equipment for generating water vapor in an automation factory
FIG. 16 is a perspective view of a conventional apparatus for exhausting water vapor.
[Explanation of symbols]
1 Steam recovery device
2 Discharge wire
3 protection net
4 Humidity sensor
5 Water receiving plate
6 Drainage pipe
7 Power unit
8 Condensation sensor
9 Trace current unit
10 Transmittance sensor
11 Cooling device
12 Airways
13 Blower means
14 Blowout opening

Claims (1)

A water vapor recovery device for applying a charge to water vapor to condense, and recovering the condensed water vapor , wherein the device for generating water vapor is provided with a pressure sensor for detecting the pressure in the water vapor generating device. The steam recovery apparatus is characterized in that the operation of the steam recovery apparatus is controlled by detecting the above.

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