JPH0349599B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a dehumidifying device for bedding that forcibly introduces air into the bedding and exhausts it from the bedding, thereby removing moisture inside the bedding. . Commercially available bedding dehumidifiers send air through a bag-like membrane with an opening and blow the air through the opening, but such devices do not maintain stable contact between the opening and the bedding. Therefore, it is difficult to perform desired ventilation according to the assumed distribution of moisture content in each part of the bedding, and it is particularly difficult to perform reliable ventilation at the side edge portions of the bedding. In addition, in order to prevent air from being released directly into the outside air from the ends of the bedding, the membrane is placed between the upper and lower bedding, and air is blown from both the upper and lower sides of the membrane. However, this method inevitably reduces the dehumidification efficiency of the lower bedding.

The present invention reliably delivers a desired proportion of air to all parts of the bedding, including the side edges, according to the assumed moisture distribution in each part, and also reliably delivers air to all parts of the bedding, in accordance with the assumed moisture distribution in each part. To provide a bedding dehumidifying device having a composite membrane through which bedding passes.
This type of air supply not only allows the blower to be made smaller by reducing the amount of power required, but also
Efficient and complete dehumidification can be achieved by laying the bed directly on a floor such as tatami mats and placing bedding on top of it.

The device of the invention has a blower for blowing air into the bedding and a composite membrane for air distribution made of a flexible material, the latter being adapted to be placed under the bedding. There is. This composite membrane forms a cylindrical body in a predetermined area that receives pressurized air sent from a blower. Therefore, when pressurized air is introduced, the tube expands and its upper surface bulges, bringing it into close contact with and lifting the bedding, thereby creating one or more gaps between it and the lower surface of the bedding. It is designed to form a closed cavity.

An opening is formed in the cylindrical body, and the air sent to the cylindrical body is discharged into the cavity through the opening. This opening is shaped to provide sufficient ventilation resistance to maintain the air pressure within the cylinder at the level necessary for lifting the bedding, and is designed to provide sufficient airflow resistance to the area other than the center of the cylinder. That is, it is placed in a portion that does not come into contact with the bedding when the cylindrical body is lifted. Therefore, air can be introduced into the gap without being obstructed by the lifted bedding.

The air released into the void passes through the cotton-like material in the bedding and is discharged to the outside of the bedding, and the evaporated moisture is discharged together with the air. Hereinafter, the effects of the present invention will be explained in detail.

FIG. 1 is a plan view of a bedding dehumidifying device according to the present invention. The blower 1 is connected to the composite membrane 3 via a connecting pipe 2. The flexible tube-forming membrane 4 forms a tube-shaped body with respect to the similarly flexible basement membrane 5, as can be seen from FIG. In the example shown in FIG. 1, the cylindrical bodies are arranged in a grid pattern.
When this cylindrical body is not receiving pressurized air, it is in a contracted and flat shape as shown in Figure 2, but when it is receiving pressurized air, it is in an expanded state as seen in the cross section of Figure 3. Bedding 6 is placed thereon to form a void 7.

Each part of the cylindrical body that receives pressurized air freely changes its cross-sectional shape according to the proportion of the bedding load borne by that part, and contacts and supports the bedding without gaps. Therefore, each cavity 7 defines one closed space, that is, one space partitioned by the cylindrical body and which does not allow air to move except through the bedding.

Figure 4 is a cross section taken along line B-B' in Figure 1.
The shape of the cavity joint when air is admitted is shown with the bedding removed.

In the attached drawing, the cylindrical bodies are arranged in four rows for convenience of explanation, but in order to distribute air evenly to all parts of the bedding and achieve a dehumidifying effect, the voids should be divided as finely as possible. It is desirable to place the

As a means of distributing air from the tubular body into the cavity formed, an opening 8 is provided in the lateral part of the cavity at a position that does not contact the raised bedding.
is bored into the cylindrical body.

The frictional resistance in the cylindrical body against the air sent from the blower, that is, the ventilation resistance h (air column), in the case of a circular cross section, is as well known as h=λl/d・v ² /2g λ: Pipe friction coefficient d: Diameter l: Cylinder length
There is a relationship between v: velocity and g: gravitational acceleration. There are 6 cylindrical bodies with a length of 1 m and a diameter of 3 cm.
Arranged in rows with a total of 3000cm ³ /s (each row 500cm ³ /s)
If , air is introduced, when λ is 0.03, the resistance h is only 0.007 m of air column. Therefore, the drop in pressure due to flow through the cylindrical body can be ignored, and it can be assumed that the same pressure is maintained in all parts of the cylindrical body. Furthermore, the ventilation resistance when forced to pass through the cotton-like material of the bedding from the void can also be ignored since the passing speed is low.

Furthermore, as will be described later, the load that the cylindrical body must bear due to the bedding is approximately several centimeters of water column, so Bernoulli's theorem regarding incompressible fluids can be applied to the relationship between pressure and flow velocity. Therefore, the blower pressure p and
If the coefficient of loss due to the air distribution opening is generally k and the specific weight of the air is r, then p/r= v ² /2g+kv ² /2g=(1+k)v ² /
The relationship 2g is established.

The loss coefficient, that is, the coefficient k of ventilation resistance, is determined by the opening 8
Determined by the shape and dimensions of. As long as the cavity 7 is formed, the opening never comes into contact with the bedding, so k does not substantially change.

From the above equation, the flow velocity v, and therefore the flow rate of air released from each individual opening into the cavity, is determined by the pressure p
and the loss coefficient k.

The air flow rate emitted from all openings is also determined by the pressure p and the individual loss coefficients. The blower to be used is selected by considering the pressure and flow rate indicated by the blowing characteristic curve in conjunction with the design regarding the ventilation resistance of the entire opening. This related design ensures that the blower pressure, i.e. the pressure within the tube, is maintained at the height required to lift the bedding while discharging the air.

An axial flow or turbo blower used as a normal hair dryer can be used as the blower of the present invention because it can easily and reliably obtain a predetermined flow rate at a predetermined pressure.

The air distribution means are distributed in each cavity in the composite membrane, but for the central cavity, a large number of or A relatively large amount of air is discharged by arranging openings with low ventilation resistance. In this regard, although only a small number of openings are shown in FIG. 1, it is desirable from the point of view of improving work efficiency to arrange as many openings as the ventilation function allows.

When bedding weighing 10 kg is placed on a composite membrane (width 1.3 m, length 1.7 m) as shown in Figure 1, and the surface area of the cylindrical body in contact with the bedding is approximately 50%, The load per cm ² of contact surface is approximately 1 g. Therefore, in this case, even if the unevenness of the contact state is taken into account, the bedding can be sufficiently supported with a pressure of approximately 2 g per cm ² (approximately 2 cm of water column). If 3000 cm ³ /sec of air is supplied to the entire composite membrane at this pressure by means of 20 similar circular apertures, the discharge rate of each individual aperture is 150 cm ³ /sec. In the above equation, if we calculate r = 1.29Kg/m ³ and k = 0.7, the flow velocity v will be 14.1m/sec. Therefore, if the diameter of each opening is 3.6mm or less, the pressure inside the cylindrical body will increase. maintained.

In order to send air to the cavity while maintaining the pressure inside the cylindrical body at the required level, a conduit extending directly from the connecting pipe 2 to the cavity, in addition to the above-mentioned opening, is used to provide a certain ventilation resistance. You can also use something.

FIG. 5 shows an air dispersion film 9 that is located above the cylindrical body and covers the cylindrical body. In the example shown in this figure, the coating has a number of strip-like pores 10 extending in a horizontal direction.
There is. When the composite membrane has this dispersion coating, one void 7 and the pore 10
Depending on the position of the air gap, the air release location within the cavity can be limited. It may be fixed to the cylinder forming membrane or may be removable.

The composite membrane used in the present invention is extremely easy to fold and otherwise store. Moreover, it goes without saying that the purpose can be achieved in a short time if the blower is a hot air blower to activate the evaporation of moisture in the bedding.

[Brief explanation of drawings]

FIG. 1 is a plan view of the dehumidification device of the present invention. FIG. 2 is a cross section taken along the chain line A-A' in FIG. FIG. 3 shows a cross section of the composite membrane with bedding placed thereon. FIG. 4 is a cross-sectional view taken along the chain line in FIG. 1 B-B', and shows the formation of a sealed cavity by the cylindrical body. FIG. 5 is a plan view when the dispersion coating is attached to the composite membrane. 1: Blower, 2: Connecting pipe, 3: Composite membrane, 4:
tube-forming membrane, 5: basement membrane, 6: bedding, 7: void,
8: Opening, 9: Air dispersion film.

Claims (1)

[Scope of Claims] 1. A non-displacement type blower, which is suitable for being placed in contact with the underside of the bedding and is connected to the blower to distribute and release the air sent from the blower under the bedding. A bedding dehumidifying device having an airtight and flexible composite membrane body, wherein the composite membrane body is preliminarily provided with a cylindrical body that can be placed in an expanded state when air is sent from a blower. formed in a defined area so that when air is delivered to the tube, the upper surface of the tube lifts the bedding and the underside of the bedding is bounded by the tube. a plurality of closed cavities are formed in the cylindrical body, and a plurality of constant areas are maintained in the lateral portions of the cylindrical body for discharging air sent to the cylindrical body into the cavities. an opening is bored in a position that does not contact the bedding when the tubular body is inflated, and the dimensions and arrangement of said openings are such that the pressure inside the tubular body provided by the blower can maintain the lifting of the bedding; and wherein the flow rate of air forced through the opening by the blower is determined to be sufficient to dehumidify the portion of the bedding covering each closed void. 2. The bedding dehumidifying device according to claim 1, wherein the composite membrane has a dispersion adjusting coating having pores on the upper side. 3. The bedding dehumidifying device according to claim 1, wherein the blower is a warm air blower.