JP2008036413A - Washing apparatus and washing method for bedding - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a washing apparatus for bedding, performing ozone sterilization in setting the bedding along the inner periphery of a rotary frame and washing and drying the bedding while rotating the rotary frame. <P>SOLUTION: In this washing apparatus for bedding, the rotary frame 2, which is formed like a cylindrical cage driven in rotation around a shaft, and in which the bedding 1 is set along the inner periphery to be freely put in and out, is disposed in a washing vessel 3. The apparatus includes: a washing means for supplying washing water to the bedding 1 from inside of the rotary frame 2 while the rotary frame 2 is driven in rotation and washing the bedding 1; a hydrating means for hydrating the bedding 1 by driving the rotary frame in rotation after washing; an ozone supply means for supplying ozone to the inside of the washing vessel 3 and ozone-sterilizing the bedding 1 while the rotary frame 2 is driven in rotation; and a drying means for blowing hot air to the bedding 1 to dry the bedding 1 while the rotary frame 2 is driven in rotation, wherein the bedding 1 can be washed, hydrated, ozone-sterilized and dried. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a bedding cleaning apparatus and a cleaning method for cleaning bedding such as a mattress.

  In hospitals and care centers, there is a growing demand for washing the bed bedding by washing it. Accordingly, a cleaning device for cleaning a large bedding such as a mattress is provided. However, since it is difficult to wash a large bedding such as a mattress, various devices have been made.

  For example, in the method of FIG. 15, first, as shown in FIG. 15A, while supplying cleaning water to the bedding 1, pressure is applied from above and below the bedding 1 as indicated by arrows, and then the bedding is washed. 1 is transferred to a dehydrator, and as shown in FIG. 15 (b), the center of the bedding 1 is sandwiched between the clamp tools 27, and the bedding 1 is rotated around the clamp tools 27 as indicated by the arrows to perform centrifugal dehydration. After this, the bedding 1 is transferred to a dryer and dried by heating.

  In the method of FIG. 16, first, as shown in FIG. 16A, the bedding 1 is folded and placed in a cylindrical rotating basket 29 and cleaning water is supplied while rotating the rotating basket 29. After the cleaning is completed and the rotating basket 29 is rotated at a high speed after dehydration, the bedding 1 is transferred to the dryer 30 as shown in FIG. The bedding 1 is placed on top of each other and heated and dried by supplying heated air from the top to the bottom as shown by the arrows.

  However, in the method of FIG. 15, a large amount of water is required for cleaning, and the bedding 1 needs to be transferred from the washing machine to the dehydrator and further to the dryer, so that it is difficult to automate from washing to dehydration. There was a problem. Further, when the bedding 1 is rotated and dehydrated by rotating the bedding 1 with the clamp 27, the bedding 1 is severely painful due to the shearing force applied to the bedding 1, and the central portion of the bedding 1 that is the center of rotation becomes insufficiently dehydrated. There was a problem.

  In addition, the method of FIG. 16 requires a large amount of water for cleaning, and the bedding 1 is folded and placed in the rotating basket 29. In particular, in the case of a mattress, there is a problem that the bent portion is easily damaged. It was. Further, since a plurality of beddings 1 are stacked and dried in the dryer 30, there is a problem that the drying efficiency of the bedding 1 located in the center and the bedding 1 located on the bottom side is poor, and a dehydrator is necessary. Although it disappears, since it was necessary to move the bedding 1 from a washing machine to a dryer, there was a problem that it was difficult to automate as in the above case.

  On the other hand, what is shown in FIG. 17 is designed to be able to continuously perform from washing to drying, and a cylindrical basket-like rotating frame 22 driven to rotate by a drive motor 21 is a washing tank (not shown). The bedding 1 is set along the inner periphery of the rotating frame 22. A washing water tank 24 is connected to a shaft tube 23 that passes through the center of the rotating frame 22, and a hot air generator 25 is installed in the vicinity of the rotating frame 22 in the washing tank (see Patent Document 1).

  And in this thing, wash water is supplied to the shaft tube 23 from the wash water tank 24, and the water spray hole provided in the shaft tube 23 is driven while rotating the rotary frame 22 in which the bedding 1 such as a mattress is set on the inner periphery. By discharging the cleaning water from 26, the cleaning water can be supplied to the inside of the bedding 1 and cleaning can be performed. At this time, since the washing water penetrates the inside of the bedding 1 well from the inside to the outside of the bedding 1 by the centrifugal force generated by the rotation of the rotating frame 22, the washing can be performed with a small amount of water. The problem that a large amount of water is required for cleaning as in the case of FIGS. 15 and 16 can be solved. Further, since the bedding 1 is set along the inner periphery of the rotating frame 22 and does not need to be folded, the problem of breakage of the bent portion as in the case of FIG. 16 can be solved.

Next, after washing is completed, the rotating frame 22 is rotated at a high speed to centrifugally dehydrate the washing water that has penetrated into the bedding 1, and then hot air is generated from the hot air generator 25, so that the bedding 1 is heated with hot air. It is heated and dried. In this way, when the rotating frame 22 is rotated at high speed and dehydrated, the bedding 1 is held in a state along the inner periphery of the rotating frame 22, so that centrifugal force acts uniformly on the entire bedding 1, and the bedding 1 can be uniformly dehydrated without causing pain, and the problem as in FIG. 15 can be solved. Moreover, since it is not necessary to put the bedding 1 on the drying, the drying can be performed efficiently, and there is no problem as shown in FIG. Furthermore, since the bedding 1 is set in the rotating frame 22 and rotated, washing, dehydration, and drying can be performed continuously, so that the trouble of transferring the bedding 1 becomes unnecessary and the operation is automated. Is possible.
JP 2002-191894 A

  Here, when washing bedding such as mattresses, it has become necessary to disinfect and sterilize bedding with ozone and the like. However, even those in Patent Document 1 cannot be sterilized by ozone, and it is desired to be able to perform ozone sterilization when cleaning bedding such as mattresses. Met.

  The present invention has been made in view of the above points. Ozone sterilization is performed when the bedding is set along the inner periphery of the rotating frame and the bedding is washed and dried while rotating the rotating frame. An object of the present invention is to provide a cleaning device and a cleaning method for bedding.

  The cleaning apparatus for bedding according to claim 1 of the present invention is formed in a cylindrical basket shape that is rotationally driven around an axis, and a rotating frame 2 in which the bedding 1 is set so as to be freely inserted and removed along the inner periphery is provided in the cleaning tank 3. In the bedding cleaning apparatus disposed and provided in the apparatus, cleaning means for cleaning the bedding 1 by supplying cleaning water to the bedding 1 from the inside of the rotary frame 2 while rotating the rotary frame 2, and after cleaning the bedding 1 Dehydrating means for rotating the rotating frame 2 to dehydrate the bedding 1, ozone supplying means for supplying ozone into the cleaning tank 3 while rotating the rotating frame 2, and ozone sterilizing the bedding 1, and ozone for the bedding 1 After the sterilization, a drying means for drying the bedding 1 by blowing warm air on the bedding 1 while rotating the rotary frame 2 is provided.

  According to this invention, while the bedding 1 is set along the inner periphery of the rotating frame 2, the bedding 1 can be continuously washed and dried while rotating the rotating frame 2, and the bedding can be performed with a small amount of water. 1 can be washed and dried without damaging the bedding 1, and can be efficiently dried. Then, the bedding 1 can be sterilized by ozone supply by the ozone supply means, and the ozone penetrates into the inside of the bedding 1 due to the centrifugal force or the collision caused by the rotation due to the rotation of the rotating frame 2. The inside of the bedding 1 can be sterilized efficiently and uniformly. Furthermore, ozone can be decomposed and detoxified by the action of warm air during drying performed after ozone sterilization, and harmful ozone is prevented from being released from the cleaning tank 3 when the bedding 1 is taken out. It is something that can be done.

  The invention of claim 2 is characterized in that, in claim 1, ozone supply is started by the ozone supply means in the middle of the step of dehydrating the bedding 1 by the dehydration means.

  According to the present invention, most of the moisture in the bedding 1 is dehydrated, and ozone sterilization is started in the middle of the dehydration process in which the moisture remaining in the bedding 1 is released as mist as the rotating frame 2 rotates. By doing so, sterilization by ozone can be performed in a state where the humidity in the cleaning tank 3 is kept high by the mist, and the effect of ozone sterilization can be enhanced.

  According to a third aspect of the present invention, in the first or second aspect, the pipe-shaped support shaft 4 is disposed at the center of the rotary frame 2 and the rotary frame 2 is rotatably attached around the support shaft 4. 4, the cleaning water supply path 5 and the hot air supply path 6 are formed, and the cleaning water is supplied to the bedding 1 through the cleaning water supply path 5 by the cleaning water supply means, and the warm air is supplied through the hot air supply path 6. It is configured to be supplied to the bedding 1 by a drying means.

  According to this invention, cleaning water and hot air can be supplied using the support shaft 4 that supports the rotating frame 2, and piping for supplying cleaning water and hot air into the rotating frame 2 can be provided. There is no need to provide it separately, and the structure can be made simple.

  The invention of claim 4 is the invention according to any one of claims 1 to 3, wherein ozone is supplied to the ozone outlet 7 of the ozone supply means for supplying ozone into the cleaning tank 3, while ozone is supplied into the cleaning tank 3. An open / close shutter 8 is provided for opening the ozone outlet 7 and closing the ozone outlet 7 while the cleaning means is operating and the drying means is operating.

  According to the present invention, the opening / closing shutter 8 can prevent the cleaning water and its moisture from entering through the ozone outlet 7 and the hot air during drying from entering through the ozone outlet 7. Can prevent these adverse effects.

  According to a fifth aspect of the present invention, the exhaust duct 9 is provided in the cleaning tank 3 in any one of the first to fourth aspects, and the exhaust duct 9 is provided with a ventilation fan 10 that operates while the drying means is operating. It is characterized by this.

  According to this invention, it is possible to perform drying while discharging the moisture in the cleaning tank 3 from the exhaust duct 9, and to improve the drying efficiency of the bedding 1.

  The invention of claim 6 is characterized in that in any one of claims 1 to 5, it comprises means for measuring the ozone concentration in the cleaning tank 3.

  According to this invention, the degree of ozone sterilization can be confirmed by measuring the ozone concentration.

  According to a seventh aspect of the present invention, in the sixth aspect, the means for measuring the ozone concentration is configured such that the air in the cleaning tank 3 is sucked from the air inlet 12 and the ozone concentration is automatically measured, and then the exhaust port 13 Is formed by an ozone concentration measuring device 11 that returns and exhausts air from the air, and opens while the ozone supply means is operating, and closes the other. The intake valve 14 is the intake port 12 and the exhaust valve 15 is the exhaust port. 13 respectively.

  According to the present invention, the intake valve 14 and the exhaust valve 15 indicate that cleaning water and its humidity enter the ozone concentration measuring device 11 and that hot air during drying enters the ozone concentration measuring device 11. It is possible to prevent the ozone concentration measuring instrument 11 from being adversely affected.

  The invention of claim 8 is characterized in that in any one of claims 1 to 7, the display device 16 for notifying the supply status of ozone to the cleaning tank 3 is provided.

  According to the present invention, it is possible to check the ozone supply status and know when to take out the bedding 1 from the cleaning tank 3.

  In the cleaning method for bedding according to claim 9 of the present invention, a rotating frame 2 formed in a cylindrical basket shape that is driven to rotate about an axis is provided in the cleaning tank 3, and the inner periphery of the rotating frame 2 is provided. The bedding 1 is set so as to be freely inserted and removed, and the rotating frame 2 is rotationally driven to supply cleaning water to the bedding 1 from the inside of the rotating frame 2 to wash the bedding 1, and after the bedding 1 is washed, the rotating frame 2 The bedding 1 is dehydrated by rotationally driving, the ozone is then sterilized by supplying ozone into the washing tank 3 while the rotating frame 2 is rotationally driven, and the bedding 1 is sterilized by ozone. The bedding 1 is dried by blowing warm air on the bedding 1 while rotating the 2.

  According to this invention, while the bedding 1 is set along the inner periphery of the rotating frame 2, the bedding 1 can be continuously washed and dried while rotating the rotating frame 2, and the bedding can be performed with a small amount of water. 1 can be washed and dried without damaging the bedding 1, and can be efficiently dried. The bedding 1 can be sterilized with ozone, and the rotation of the rotating frame 2 allows ozone to easily penetrate into the bedding 1 due to a centrifugal force or a collision caused by the rotation. It can be sterilized. Furthermore, ozone can be decomposed and detoxified by the action of warm air during drying performed after ozone sterilization, and harmful ozone is prevented from being released from the cleaning tank 3 when the bedding 1 is taken out. It is something that can be done.

  Further, the invention of claim 10 is that in claim 9, ozone is sterilized by supplying ozone into the cleaning tank 3 in the middle of the process of rotating and driving the rotating frame 2 to dehydrate the bedding 1. It is a feature.

  According to the present invention, most of the moisture in the bedding 1 is dehydrated, and sterilization by ozone is started in the middle of the dehydration process in which the moisture remaining in the bedding 1 is released as mist as the rotating frame 2 rotates. By doing so, sterilization by ozone can be performed in a state where the humidity in the cleaning tank 3 is kept high by the mist, and the effect of ozone sterilization can be enhanced.

  The invention of claim 11 is characterized in that, in claim 10, the rotational speed of the rotary frame 2 in the dehydration step is increased when ozone is supplied into the cleaning tank 3.

  According to the present invention, by increasing the rotation speed of the rotating frame 2, moisture remaining in the bedding 1 can be easily released as mist, and the effect of ozone sterilization can be enhanced.

  Further, the invention of claim 12 is the invention according to any one of claims 9 to 11, wherein ozone is sterilized by supplying ozone into the cleaning tank 3, and then the bedding 1 is dried by blowing warm air on the bedding 1. In this case, the supply of ozone into the cleaning tank 3 is stopped, and after a predetermined time has elapsed since the start of blowing warm air to the bedding 1, the ventilation fan 10 of the exhaust duct 9 provided in the cleaning tank 3 is operated. It is a feature.

  According to the present invention, by performing drying while operating the ventilation fan 10 of the exhaust duct 9, it is possible to perform drying while exhausting the moisture in the cleaning tank 3 from the exhaust duct 9, and efficiently drying the bedding 1. Can be performed. The ozone in the washing tub 3 is decomposed by the action of warm air, but the ventilation fan 10 operates after a predetermined time has elapsed since the start of blowing warm air to the bedding 1, so for a while after the start of blowing warm air. Even if undecomposed ozone remains in the cleaning tank 3, it can be prevented from being released to the outside by the operation of the ventilation fan 10.

  According to the present invention, while the bedding 1 is set along the inner periphery of the rotating frame 2, the bedding 1 can be continuously washed and dried while rotating the rotating frame 2, and the bedding can be performed with a small amount of water. 1 can be washed and dried without damaging the bedding 1, and can be efficiently dried. The bedding 1 can be sterilized with ozone, and the rotation of the rotating frame 2 allows ozone to permeate into the bedding 1 due to a centrifugal force or a collision caused by the rotation, so that the bedding 1 can be efficiently and evenly distributed. It can be sterilized. Furthermore, ozone can be decomposed and detoxified by the action of warm air during drying performed after ozone sterilization, and harmful ozone is prevented from being released from the cleaning tank 3 when the bedding 1 is taken out. It is something that can be done.

  Hereinafter, the best mode for carrying out the present invention will be described.

  FIG. 4 shows the entire cleaning apparatus of the present invention, and instrument casings 35 and 36 are provided on both sides of the cleaning tank 3. A central portion of the front surface of the cleaning tank 3 is formed as an opening 37, and a door 38 that opens and closes the opening 37 by sliding up and down is attached to the opening 37.

  A rotating frame 2 as shown in FIGS. 1 to 3 and 5 is provided in the cleaning tank 3. 1 and 2 show a preparation stage for inserting the bedding 1 into the rotating frame 2. The rotating frame 2 is spanned between annular side frames 40 on both sides, and a plurality of horizontal frames 41 are attached at predetermined intervals, and a plurality of thin frames 42 are connected to the side frames 40 across the horizontal frames 41. It consists of a cylindrical cylinder body 43 formed by attaching them in parallel. A plurality of support rods 45 are radially attached to the outer periphery of the shaft ring 44, and the tip of each support rod 45 is attached to the inner periphery of the side frame 40, so that the cylinder cage body 43 is pivoted via the support rod 45. The rotating frame 2 is formed by being supported by a ring 44.

  In a part of the cylindrical car body 43 of the rotating frame 2, a portion not provided with the horizontal frame 41 or the thin frame 42 is formed as shown in FIG. 5, and this opening portion puts the bedding 1 in and out of the rotating frame 2. It becomes the entrance / exit 46. A grid-like opening / closing door 51 is attached to the outer side of the cylindrical car body 43 so as to be slidable in the circumferential direction, and the door 46 can be opened and closed by the opening / closing door 51.

  A plurality of guide bars 47 are attached to the inside of the cylindrical car body 43 in parallel with the cylindrical car body 43. This guide bar 47 is fixed to a mesh plate 48 installed between opposing support bars 45 attached to the side frames 40 on both sides, or to a connecting bar 49 provided between other support bars 45. It is designed to be attached inside the cylindrical car body 43. By inserting the bedding 1 between the guide rod 47 and the inner periphery of the cylindrical car body 43, the bedding 1 can be held and set along the inner periphery of the rotating frame 2.

  As shown in FIGS. 1 and 2, the support base 53 is formed in a U-shape with an upward opening by providing side support frames 54 on both sides, and the support base 53 is accommodated in the cleaning tank 3. Yes. The support shaft 4 is horizontally mounted and fixed between the upper portions of the side support frames 54 on both sides of the support base 53. The support shaft 4 is formed in a cylindrical pipe shape, and the rotary frame 2 is disposed in the cleaning tank 3 by attaching a pair of left and right shaft rings 44 of the rotary frame 2 to the outer periphery of the support shaft 4 in a rotatable manner. It is. A driven pulley 55 is fixed to one of the pair of left and right shaft rings 44, and a belt 58 is provided between the driven pulley 57 of the motor 56 attached to the support base 53 below the support shaft 4 and the driven pulley 55. It is suspended. Accordingly, by operating the motor 56 and rotating the driving pulley 57, the driven pulley 55 can be rotated via the belt 58, and the rotating frame 2 can be driven to rotate in the vertical direction around the support shaft 4 as the center of rotation. It is.

  As shown in FIG. 5, the inside of the support shaft 4 formed in the shape of the cylindrical pipe is partitioned up and down by a partition plate 60 over the entire length of the support shaft 4, and the lower side of the partition plate 60 in the support shaft 4. Is formed as a washing water supply path 5, and the upper side is formed as a hot air supply path 6.

  Further, water spray ports 61 are formed at a plurality of locations along the axial direction in the lower portion of the support shaft 4 in the portion of the cleaning water supply passage 5, and as shown in FIG. A cleaning water supply pipe 62 is connected to the supply path 5. The cleaning water supply pipe 62 is connected to the water pipe 64 via the electromagnetic valve 63, and a pair of branch pipes 65, 66 are connected to the cleaning water supply pipe 62, and each branch pipe 65, 66 is connected. Are connected to a detergent tank 69 and a disinfectant tank 70 via pumps 67 and 68, respectively. From these cleaning water supply path 5, water spout 61, cleaning water supply pipe 62, solenoid valve 63, water pipe 64, branch pipes 65 and 66, pumps 67 and 68, detergent tank 69, disinfectant tank 70, etc. The cleaning means of the invention is formed.

  Further, a pair of hot air supply pipes 73 communicated with the inside of the hot air supply path 6 as shown in FIG. 5 are erected upwardly as shown in FIG. An inner warm air blowing nozzle 74 is attached across the upper end of the supply pipe 73. The inner hot air blowing nozzle 74 is disposed on the inner side of the rotating frame 2 along the substantially entire length of the rotating frame 2 in the axial direction. The inside warm air blowing nozzle 74 is communicated with the inside of the warm air supply pipe 73, and a nozzle hole 75 is opened along the upper end of the inside warm air blowing nozzle 74 as shown in FIG. An electric hot air heater 76 is installed in the instrument casing 35, and a hot air pipe 77 is led out from the electric hot air heater 76. The end of the branch hot air pipe 78 branched from the hot air pipe 77 is the end of the support shaft 4 opposite to the side connected to the washing water supply pipe 62, and the hot air supply path in the support shaft 4 6 is connected.

  Further, as shown in FIGS. 1 and 2, an outer warm air blowing nozzle 79 is disposed outside the rotating frame 2 along substantially the entire axial length of the rotating frame 2. The hot air pipe 77 led out from the electric warm air machine 76 is raised along the side of the rotating frame 2 as shown in FIG. 2, and the tip of the hot air pipe 77 is one end of the outer hot air outlet nozzle 79. Is connected to. The outside warm air blowing nozzle 79 communicates with the inside of the warm air piping 77, and a nozzle hole (not shown) is opened along the lower end of the outside warm air blowing nozzle 79. The drying means of the present invention includes the electric hot air machine 76, the hot air pipe 77, the branch hot air pipe 78, the hot air supply path 6, the hot air supply pipe 73, the inner hot air blowing nozzle 74, the outer hot air blowing nozzle 79, and the like. Is formed.

  An ozone generator 85 and an air pump 86 are installed in the instrument casing 36. The ozone generator 85 is provided with an ozone outlet 7 leading out, and the tip of the ozone outlet 7 is introduced into the cleaning tank 3 through a wall 87 between the cleaning tank 3 and the instrument casing 36 as shown in FIG. The tip of the ozone outlet 7 is arranged so as to face the side of the rotating frame 2 as shown in FIGS. The ozone gas generated by the ozone generator 85 is blown into the cleaning tank 3 through the ozone outlet 7 by the air supplied from the air pump 86. As shown in FIG. 7, an opening / closing shutter 8 is provided in the ozone outlet 7 so that the ozone outlet 7 can be opened and closed. The ozone supply means of the present invention is formed from the ozone generator 85, the air pump 86, the ozone outlet 7 and the like.

  Further, in the instrument casing 36, an ozone concentration measuring device 11 is installed as means for measuring the ozone concentration as shown in FIG. The intake port 12 and the exhaust port 13 provided in the ozone concentration measuring device 11 are attached to the cleaning tank 3 by being opened through the wall 87 and the pump built in the ozone concentration measuring device 11 is operated to operate the cleaning tank 3. The air inside is sucked into the ozone measuring device 11 from the air inlet 12 and the ozone concentration is measured, and then returned to the cleaning tank 3 from the exhaust port 13 to be exhausted. The ozone concentration measuring device 11 is formed, for example, with a built-in detection unit formed by an ultraviolet absorption ozone gas monitor or the like that measures the ozone concentration by detecting the amount of absorption of ultraviolet rays by ozone. . An intake valve 14 and an exhaust valve 15 are provided in the intake port 12 and the exhaust port 13, respectively, so that the intake port 12 and the exhaust port 13 can be opened and closed.

  Further, an exhaust duct 9 is connected to the cleaning tank 3 as shown in FIG. 9A so that the air in the cleaning tank 3 can be discharged to the outside through the exhaust duct 9. An exhaust fan 10 is provided in the exhaust duct 9, and an open / close shutter 81 is provided in the exhaust duct 9 at a position closer to the cleaning tank 3 than the exhaust fan 10. The exhaust fan 10 is supported by a vibration isolating rubber 126 on a support 125 provided on the outer surface of the cleaning tank 3. Furthermore, an intake duct 82 is connected to the cleaning tank 3 as shown in FIG. 9B, and when the air in the cleaning tank 3 is exhausted by the exhaust duct 9, the outside air in the room where the cleaning device is installed is taken into the intake duct. The air is sucked into the cleaning tank 3 from 82. The intake duct 82 is provided with an intake valve 83 that opens when the air in the cleaning tank 3 is exhausted by the exhaust duct 9 and closes otherwise. The ends of the exhaust duct 9 and the intake duct 82 are exposed to the outer surface of the apparatus through the outer casing 84 of the apparatus.

  Moreover, the display 16 is attached to the outer surface of the cleaning tank 3 or the instrument casings 35 and 36 as shown in FIG. 4 so as to notify the supply status of ozone into the cleaning tank 3. The display 16 is formed of, for example, a red lamp 16a, a yellow lamp 16b, and a green lamp 16c, and notifies the ozone supply status by lighting each of the lamps 16a, 16b, and 16c.

  FIG. 10 shows a control system of the cleaning apparatus of the present invention. The cleaning machine controller 88 is a motor 56 for rotationally driving the rotary frame 2, an electromagnetic valve 63 for the cleaning water supply pipe 62, and pumps 67 and 68 Is referred to as a washing machine operating unit 89), an electric warm air machine 76, and an intake duct 82. The ozone generation controller 90 controls the ozone concentration measuring device 11, the ozone generator 85, the air pump 86, the ventilation fan 10 of the exhaust duct 9, and the open / close shutter 81. A data logger 91 and a recorder 92 are connected to the ozone generation controller 90. The data logger 91 stores the ozone concentration data and outputs it to a personal computer, and the recorder 92 outputs the ozone concentration data to a recording sheet. I can do it.

  FIG. 11 shows an ozone gas control panel 94 for controlling the ozone generation controller 90, the ozone concentration measuring device 11, the ozone generator 85, and the air pump 86, 95 is a power switch, and 96 is an ozone generator automatically. , A changeover switch 97 for manually generating ozone, 98 an ozone generation on switch for manually generating ozone, and 99 for setting an ozone generation time for manually generating ozone. A timer dial 100 is a display lamp that displays whether ozone generation is performed automatically or manually. The display 16 may be provided on the ozone gas control panel 94 as shown in FIG.

  Next, an operation of cleaning the bedding 1 such as a mattress using the cleaning device of the present invention will be described. First, the door 38 of the washing tank 3 is pushed up to open the opening 37 as shown in FIG. 4, and the door 51 is slid by sliding the opening / closing door 51 in a state where the opening 37 is aligned with the opening 37. And the bedding 1 is set in the rotating frame 2 from the entrance 46. At this time, the bedding 1 is fixed and set in a state along the inner periphery of the rotating frame 2 by inserting the bedding 1 between the inner periphery of the cylindrical car body 43 of the rotating frame 2 and the guide rod 47. It is something that can be done. For example, two beddings 1 can be set in the rotating frame 2. Thereafter, the opening / closing door 51 is slid to close the entrance / exit 46 of the rotating frame 2, and the door 38 is pulled down to close the opening 37 of the cleaning tank 3.

  In this state, when the washing machine controller 88 and the ozone generation controller 90 are operated, the rotating frame 2 is driven to rotate, and the washing process including the washing and rinsing, the dehydration process, the ozone sterilization process, and the drying process are automatically performed continuously. Done. FIG. 12 shows a time chart of these steps. For example, the cleaning step is performed by washing for 2 minutes and rinsing for 6 minutes, and then the dehydration step is performed by performing dehydration for 75 minutes. In addition, the ozone sterilization step is performed for 50 minutes in parallel with the dehydration step from the middle of the dehydration step after 25 minutes from the start of the dehydration, and then the drying step is performed for 40 minutes. The rotation speed of the rotating frame 2 is set to 90 rpm for cleaning, slightly increased to 180 rpm for rinsing, further increased to 240 rpm for dehydration, and used for ozone sterilization. Is set to 260 rpm at a higher rotation speed, and is set to 102 rpm by reducing the speed during drying. Of course, the time of each process and the rotational speed of the rotating frame 2 are not limited to these.

  Here, at the time of cleaning, the electromagnetic valve 63 is opened, and tap water is supplied from the water pipe 64 to the cleaning water supply pipe 62. At this time, the pumps 67 and 68 are further operated to remove the detergent from the detergent tank 69. However, the sterilizing agent is supplied from the sterilizing agent tank 70 to the cleaning water supply pipe 62, and is supplied into the cleaning water supply path 5 of the support shaft 4 in a state where at least one of the detergent and the sterilizing agent is mixed with water. The washing water containing the detergent is sprayed downward from the water spout 61 of the support shaft 4 in the rotating frame 2, and the bedding set on the inner periphery of the rotating frame 2 as the rotating frame 2 rotates. The washing water containing the detergent can be uniformly supplied to the entire surface of 1. Further, since the bedding 1 is rotated by the rotating frame 2, the washing water containing the detergent supplied to the inner peripheral side of the bedding 1 penetrates into the inside from the inner surface side of the bedding 1 by the centrifugal force to the outer surface side. As a result, the wash water can efficiently penetrate into the bedding 1, and the bedding 1 can be efficiently washed.

  Next, at the time of rinsing, the operations of the pumps 67 and 68 are stopped, and rinse water for rinsing that is not mixed with detergent and disinfectant is supplied to the rinse water supply pipe 62, and the rinse water for rinse is supplied. Water is sprayed from the water spout 61. Also at this time, as the rotating frame 2 rotates, the rinsing water for rinsing can be uniformly supplied to the entire surface of the bedding 1 set on the inner periphery of the rotating frame 2. The washing water for rinsing penetrates from the inner surface side of the bedding 1 to the outer surface side due to the centrifugal force caused by the rotation, and the rinsing washing water can efficiently penetrate into the bedding 1; The bedding 1 can be rinsed efficiently.

  When the rinsing is finished, the solenoid valve 63 is closed and the supply of cleaning water is stopped. Then, by rotating the rotating frame 2 at a higher rotational speed, centrifugal dehydration is performed in which the washing water in the bedding 1 is dehydrated by centrifugal force. In the present invention, the dehydrating means is formed of the rotating frame 2 and the motor 56 that rotates the rotating frame 2. When dehydrating, as shown in the time chart of FIG. 12, the opening / closing shutter 81 of the exhaust duct 9 is opened and the ventilation fan 10 is operated to exhaust the moisture in the cleaning tank 3 through the exhaust duct 9. Is done efficiently. Thus, when the moisture in the cleaning tank 3 is discharged from the exhaust duct 9, the intake valve 83 of the intake duct 82 is open.

  In this way, the ozone sterilization process starts during the dehydration process in which the rotating frame 2 is rotationally driven to dehydrate the cleaning water in the bedding 1. When the ozone sterilization process is started, the open / close shutter 81 of the exhaust duct 9 is closed and the ventilation fan 10 is stopped.

  In the ozone sterilization process, as shown in the time chart of FIG. 12, the ozone generator 85 and the air pump 86 are operated, the open / close shutter 8 of the ozone outlet 7 is opened, and the ozone gas generated by the ozone generator 85 is discharged into the ozone outlet. 7 is blown into the washing tank 3. By supplying ozone to the washing tank 3 in this way, the bedding 1 can be sterilized with ozone. Since this ozone sterilization is performed while the rotary frame 2 is driven to rotate, ozone easily penetrates into the bedding 1 due to a collision caused by centrifugal force and rotation, and the inside of the bedding 1 can be sterilized efficiently and uniformly. It is something that can be done. At this time, the open / close shutter 8 of the ozone outlet 7 is opened only when the ozone generator 85 is operated in the ozone sterilization process, and is closed in other cleaning processes and drying processes. Is prevented from entering the ozone generator 85 from the ozone outlet 7, and the ozone generator 85 is prevented from being adversely affected by these.

  Here, when ozone gas is used for sterilization, it is known that the sterilization effect is low in a dry atmosphere and the sterilization effect is high in a high humidity state. This is because ozone gas itself does not have bactericidal power, but ozone gas reacts with water in contact with water to generate nascent oxygen and OH radicals. This is because sterilization is performed by the action. Therefore, it is possible to obtain a high effect of ozone sterilization in an atmosphere with high humidity and a lot of moisture. For example, the sterilization effect by ozone is small in a dry atmosphere having a relative humidity of 45% RH or less, and a high sterilization effect by ozone can be obtained in an atmosphere having a high humidity of 80% RH or more. Table 1 shows the relationship between ozone concentration and humidity with respect to the ozone sterilization effect (“New version of ozone utilization technology”, Sanyu Shobo, Chapter 12 “Method of using ozone in medicine” (Ryosuke Murayama) 459 The page data was processed). As shown in Table 1, in order to obtain a sterilization rate of 99.999% by ozone irradiation for 15 minutes, when the relative humidity is 30%, the ozone concentration needs to be 30-80 ppm. The ozone CT value, which is the product of the exposure time, is 450 to 1200 (ppm · min), but if the relative humidity is 80%, the ozone concentration may be 25 ppm and the ozone CT value is 375 (ppm · min). Just do it.

  Thus, in the ozone sterilization process, in order to effectively sterilize the bedding 1 with ozone, it is necessary that the humidity in the cleaning tank 3 is high. Therefore, in the present invention, ozone gas supply is started in the middle of the dehydration process in which the humidity in the cleaning tank 3 is high, and the ozone sterilization process is performed in parallel with the dehydration process. Here, at the initial stage of the dehydration process, a large amount of water is contained in the bedding 1, and ozone cannot penetrate into the bedding 1, so that the moisture content of the bedding 1 becomes 10 to 20% by mass. After dehydration proceeds, the supply of ozone is started. In the embodiment of FIG. 12, the water content of the bedding 1 becomes 10 to 20% by mass after about 25 minutes from the start of dehydration. When the water content of the bedding 1 is lowered in this manner and the rotary frame 2 is driven to rotate and dehydration is continued, the water remaining in the bedding 1 is released as mist by centrifugal force, and this mist is washed into the washing tank 3. The inside of the cleaning tank 3 is maintained at a relative humidity of 80% or more. In particular, in the present invention, simultaneously with the start of ozone supply, the rotational speed of the rotating frame 2 is increased by 10 to 40 rpm (preferably about 20 rpm), and the mist is efficiently released with high centrifugal force from the bedding 1 having a low moisture content. It is supposed to be. In this way, ozone can be supplied and ozone can be sterilized with a high sterilizing effect by supplying ozone while keeping the humidity in the cleaning tank 3 high with mist.

  Further, as shown in the time chart of FIG. 12, the ozone concentration measuring device 11 is always operating during operation of the cleaning device, but is provided at the intake valve 14 and the exhaust port 13 provided at the intake port 12 of the ozone concentration measuring device 11. The exhaust valve 15 is operated in conjunction with the operation of the ozone generator 85, and the intake valve 14 and the exhaust valve 15 are opened only during the operation of the ozone generator 85, and are closed in other cleaning processes and drying processes. ing. Therefore, while ozone is sterilized by supplying ozone from the ozone generator 85 to the cleaning tank 3, the air in the cleaning tank 3 is sucked into the ozone concentration measuring device 11 from the inlet 12 and returned from the exhaust 13. The ozone concentration in the cleaning tank 3 is measured. In addition, since the intake valve 14 and the exhaust valve 15 are closed in the cleaning process and the drying process, it is possible to prevent cleaning water, moisture, and the like from entering the ozone concentration measuring device 11 from the intake port 12 and the exhaust port 13. The ozone concentration measuring device 11 can be prevented from being adversely affected by these.

  Here, the degree of ozone sterilization can be confirmed by the ozone CT value, which is the product of the ozone concentration and the time of exposure to ozone, and thus the ozone concentration in the cleaning tank 3 is measured by the ozone concentration measuring device 11. By measuring this, the degree of ozone sterilization of the bedding 1 can be confirmed. The supply of ozone from the ozone generator 85 to the cleaning tank 3 is not only controlled by time control such as a timer, but the ozone CT value obtained from the ozone concentration output value measured by the ozone concentration measuring device 11 is previously set. It can also be controlled to automatically stop when it reaches a set value.

  When the ozone sterilization process in parallel with the dehydration process is finished, as shown in the time chart of FIG. 12, the operation of the ozone generator 85 is stopped and the electric hot air heater 76 is operated and heated by the heater of the electric hot air heater 76. Hot air is sent out to the hot air piping 77 by a fan. This hot air is supplied from the hot air pipe 77 to the branch hot air pipe 78, the hot air supply path 6 in the support shaft 4, and the hot air supply pipe 73 to the inner hot air outlet nozzle 74 disposed inside the rotating frame 2. The warm air is blown from the inner warm air blowing nozzle 74 that faces and is close to the inner side of the bedding 1 set on the inner periphery of the rotating frame 2. Further, the warm air is supplied from the warm air pipe 77 to the outer warm air blowing nozzle 79 disposed outside the rotating frame 2, and the outer temperature facing the outer side of the bedding 1 set on the inner periphery of the rotating frame 2 is opposed to the outer temperature. Hot air is blown from the air blowing nozzle 79. In the drying process, warm air is blown from both sides of the bedding 1 in this way, and since warm air is uniformly blown over the entire surface of the bedding 1 as the rotating frame 2 rotates, the bedding 1 is dried. Can be performed efficiently and uniformly.

  In this drying process, as shown in the time chart of FIG. 12, the opening / closing shutter 81 of the exhaust duct 9 is opened and the ventilation fan 10 is operated to exhaust moisture in the cleaning tank 3 through the exhaust duct 9. Drying is performed efficiently. Here, as shown in the flowchart of FIG. 12, the ventilation fan 10 is operated after a predetermined time (for example, 3 minutes) has elapsed since the operation of the electric hot air heater 76. When warm air is supplied from the electric warm air machine 76 into the cleaning tank 3 through the inner warm air blowing nozzle 74 and the outer warm air blowing nozzle 77, the ozone in the washing tank 3 is decomposed by the heat of the warm air and harmless oxygen. However, there is a high possibility that ozone that has not been decomposed remains in the cleaning tank 3 at the initial stage of the operation of the electric hot air heater 76. For this reason, the ventilation fan 10 is not operated for a predetermined time after the electric hot air heater 76 is operated, so that harmful ozone in the cleaning tank 3 is prevented from being discharged from the exhaust duct 9 to the outside. It is what.

  As shown in the flowchart of FIG. 12, in the ozone sterilization process in which the ozone generator 85 is operated, the red lamp 16 a of the display 16 is turned on to indicate that ozone is supplied to the cleaning tank 3. It is like that. In the next drying step after the ozone sterilization step, the yellow lamp 16b is turned on to indicate that drying is in progress. Further, when the drying process is completed, the green lamp 16c is turned on to display that the door 38 of the cleaning tank 3 can be opened and the bedding 1 can be taken out. At this time, the door 38 is locked so that it cannot be opened from the washing process to the drying process. When the green lamp 16c is lit in this way, the lock is released and the door 38 is opened and closed. A chime to let you know what you can do is sounded.

  As described above, the steps up to cleaning of bedding, dehydration, ozone sterilization, and drying can be continuously and automatically operated. However, the cleaning device of the present invention allows only ozone sterilization to be performed. It is.

  In the case where the washing, dehydration, ozone sterilization and drying processes are automatically operated as described above, the operation is performed with the changeover switch 96 of the ozone gas control panel 94 turned on. 97 is turned on and switched to manual operation. After setting the operation time with the timer dial 99, the ozone generation ON switch 98 is turned on, so that the rotation frame 2 is driven to rotate while the rotation frame 2 is rotated. The device 85 can be operated to sterilize the bedding 1 with ozone.

  A time chart at this time is shown in FIG. Similarly to the above, the ozone concentration measuring device 11 is always operating, but the intake valve 14 and the exhaust valve 15 of the ozone concentration measuring device 11 are opened simultaneously with the operation of the ozone generator 85 to adjust the ozone concentration in the cleaning tank 3. The degree of ozone sterilization of the bedding 1 can be confirmed by measurement. When the operation of the ozone generator 85 is stopped, the electric hot air blower 76 is operated for a predetermined time (for example, 3 minutes), and hot air is supplied into the cleaning tank 3 from the inner hot air blowing nozzle 74 or the outer hot air blowing nozzle 79. The ozone in the cleaning tank 3 is decomposed into harmless oxygen by the heat of the warm air. When the operation of the ozone generator 85 is stopped, the opening / closing shutter 81 of the exhaust duct 9 is opened and the ventilation fan 10 is operated, but after a predetermined time (for example, 3 minutes) has elapsed while the electric hot air heater 76 is operating. The ventilation fan 10 is operated, and harmful ozone in the cleaning tank 3 is not discharged outside from the exhaust duct 9 without being decomposed. Even when only this ozone sterilization is performed, the door 38 of the cleaning tank 3 is locked and cannot be opened during operation.

  In the above-described embodiment, the ozone concentration measuring device 11 that can automatically measure the ozone concentration is used as a means for measuring the ozone concentration. However, the ozone concentration measuring device 11 is an expensive device and is replaced with this. Thus, the ozone indicator 102 that changes color according to the ozone concentration may be used.

  FIG. 14 shows a structure in which the ozone indicator 102 is attached to the cleaning tank 3, and a receiving cylinder 105 is attached to an attachment hole 104 provided in the wall 103 of the cleaning tank 3. The receiving cylinder 105 is formed by providing a flange 107 on the outer periphery of one end of the cylindrical portion 106 having both ends opened. The receiving cylinder 105 is fixed to the wall 103 with a bolt nut 108 passed through the flange 107 as shown in FIG. is there. The ozone indicator 102 is set on the indicator holder 109 and attached to the receiving tube 105. As shown in FIGS. 14B and 14C, the indicator holder 109 is provided with a mounting plate 111 that closes the other end of the holding cylinder 110 that opens at one end and projects to the outer periphery of the holding cylinder 110. The U-shaped insertion piece 112 is attached so as to face each other with a small gap. The ozone indicator 102 can be set in the indicator holder 109 by inserting the ozone indicator 102 into the small gap between the insertion pieces 112, and a packing 113 such as silicon rubber is inserted between the insertion pieces 112. Thus, the ozone indicator 102 can be positioned and fixed. 14D, the holding cylinder 110 of the indicator holder 109 is inserted into the cylindrical portion 106 of the receiving cylinder 105, and the mounting plate 111 is overlapped on the outer surface of the flange 107 via a packing 120 such as silicon rubber. The indicator holder 109 can be attached by screwing the thumbscrew 121 passed through the attachment plate 111 into the flange 107, and the ozone indicator 102 passes through the opening of the holding cylinder 110 of the indicator holder 109 and the cleaning tank 3. It comes in contact with the air inside.

  When ozone is supplied from the ozone generator 85 into the cleaning tank 3, the ozone acts on the ozone indicator 102 in the indicator holder 109. The ozone indicator 102 changes color so as to be decolored by the action of ozone, and this color change increases as the ozone concentration increases and increases as the time of exposure to ozone increases. Therefore, by removing the indicator holder 109, taking out the ozone indicator 102, and reading the progress of discoloration of the ozone indicator, the ozone CT value can be detected and the degree of ozone sterilization can be confirmed. .

It is a perspective view which shows a part of example of embodiment of this invention. It is a perspective view which shows a part same as the above. It is a perspective view which shows a part same as the above. It is a schematic front view same as the above. It is sectional drawing of the part of a rotation frame same as the above. It is the schematic which shows a part same as the above. It is the schematic which shows a part same as the above. It is the schematic which shows a part same as the above. It shows a part of the above, and (a) and (b) are schematic views respectively. It is a block diagram which shows a control system same as the above. It is a partial front view same as the above. It is a time chart which shows operation | movement same as the above. It is a time chart which shows operation | movement same as the above. It shows a part of the above, (a) is a sectional view, (b) a front view, (c) is a rear view, (d) is a sectional view. A conventional example is shown, and (a) and (b) are schematic views respectively. Another conventional example is shown, and (a) and (b) are schematic views, respectively. It is a perspective view which shows another prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Bedding 2 Rotating frame 3 Washing tank 4 Support shaft 5 Washing water supply path 6 Warm air supply path 7 Ozone outlet 8 Opening / closing shutter 9 Exhaust duct 10 Ventilation fan 11 Ozone concentration measuring instrument 12 Inlet 13 Exhaust 14 Intake valve 15 Exhaust Valve 16 indicator

Claims (12)

  In the bedding cleaning device, which is formed in the shape of a cylindrical basket that is driven to rotate around an axis and in which the bedding is set along the inner periphery, the rotating frame is driven to rotate. While cleaning the bedding by supplying cleaning water to the bedding from the inside of the rotating frame, dehydrating means for rotating the rotating frame to dehydrate the bedding after cleaning the bedding, and rotating the rotating frame Ozone supply means for supplying ozone into the cleaning tank and sterilizing the bedding with ozone; and drying means for drying the bedding by spraying warm air on the bedding while rotating the rotating frame after the bedding is sterilized with ozone. A bedding cleaning apparatus comprising:   2. The bedding cleaning apparatus according to claim 1, wherein supply of ozone is started by the ozone supply means in the middle of the step of dehydrating the bedding by the dehydration means.   A pipe-shaped support shaft is disposed at the center of the rotating frame, and the rotating frame is rotatably mounted around the supporting shaft. The inside of the supporting shaft is partitioned to form a cleaning water supply path and a hot air supply path. 3. The bedding according to claim 1, wherein cleaning water is supplied to the bedding by the cleaning water supply means through the supply path, and hot air is supplied to the bedding by the drying means through the hot air supply path. Cleaning equipment.   While supplying ozone into the cleaning tank, the ozone outlet is opened to the ozone outlet of the ozone supply means for supplying ozone into the cleaning tank, and the drying means is operated while the cleaning means is operating. The bedding cleaning apparatus according to any one of claims 1 to 3, further comprising an open / close shutter that closes the ozone outlet while the air is being discharged.   The apparatus for cleaning a bedding according to any one of claims 1 to 4, wherein an exhaust duct is provided in the cleaning tank, and a ventilation fan is provided in the exhaust duct that operates while the drying means is operating. .   The bedding cleaning apparatus according to any one of claims 1 to 5, further comprising means for measuring an ozone concentration in the cleaning tank.   The ozone concentration is measured by an ozone concentration meter that measures the ozone concentration by inhaling the air in the cleaning tank through the intake port, automatically measuring the ozone concentration, and then returning the air from the exhaust port to exhaust the ozone. 7. The bedding cleaning apparatus according to claim 6, further comprising: an intake valve provided at an intake port and an exhaust valve provided at an exhaust port, which are opened while the supply means is operating and closed otherwise.   The bedding cleaning apparatus according to any one of claims 1 to 7, further comprising a display device for notifying a supply state of ozone to the cleaning tank.   A rotating frame formed in the shape of a cylindrical basket that is driven to rotate around an axis is arranged in the cleaning tank, and the bedding is set freely along the inner periphery of the rotating frame, and the rotating frame is rotated. Cleaning water is supplied to the bedding from the inside of the rotating frame to wash the bedding, and after the bedding is washed, the bedding is dehydrated by rotating the rotating frame, and then the ozone is cleaned while rotating the rotating frame. A bedding cleaning method, comprising: supplying bedding into a tank and sterilizing bedding with ozone, sterilizing the bedding with ozone, and then spraying warm air on the bedding while rotating the rotating frame to dry the bedding.   The bedding cleaning method according to claim 9, wherein ozone is sterilized by supplying ozone into the cleaning tank in the middle of the step of rotating the rotating frame to dehydrate the bedding.   The method for cleaning a bedding according to claim 10, wherein the rotation speed of the rotating frame in the dehydration step is increased when ozone is supplied into the cleaning tank.   After supplying ozone into the cleaning tank and sterilizing the bedding with ozone, when blowing hot air onto the bedding and drying the bedding, we stopped supplying ozone into the cleaning tank and started blowing hot air onto the bedding. The bedding cleaning method according to any one of claims 9 to 11, wherein a ventilation fan of an exhaust duct provided in the cleaning tank is operated after a predetermined time has elapsed.

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