KR102583996B1 - Mask having Cooling Means - Google Patents

Abstract

The present invention relates to a mask equipped with a cooling means, comprising: a mask body 200 in contact with the wearer's face and having a viewing window 210 formed on the front; a cooling air injection unit 112 formed on a predetermined portion of the mask body 200 to introduce cooling air into the space between the mask body and the wearer's face; A tube 120 whose end is connected to the cooling air injection unit 112; A plurality of spray nozzles 121 formed on the tube 120 to spray cooling air into the space between the mask body and the wearer's face; and a cooling air discharge unit 110 for discharging the cooling air sprayed through the spray nozzle 121 to the outside of the mask.

Description

Mask having Cooling Means

The present invention relates to masks, and more particularly to full-face masks equipped with means for cooling the wearer's face and preventing fogging of the viewing window.

Industrial full-face masks are generally used in factories, construction sites, etc. to protect the wearer from harmful substances such as dust, smoke, gas, and vapor. These masks can be worn over the entire face, protecting the wearer's entire face.

Because a full-face mask covers and seals the wearer's entire face, the humidity and temperature inside the full-face mask tend to increase during long-term use, and this environment can have a negative impact on work efficiency. In particular, in a high-temperature and humid work environment, the wearer easily sweats, and moisture may accumulate inside the viewing window of the full-face mask, blocking the view. However, it was difficult to wipe off the sweat or clean the viewing window due to the full-face mask. In order to increase work efficiency, it is necessary to prevent the wearer's facial temperature and humidity from becoming excessively high.

Figure 1 shows a conventional full-face mask, and there is a known technology for supplying oxygen from a compressed oxygen bottle carried by the wearer to the full-face mask through a tube. However, the above technology only supplies oxygen to help the wearer with oxygen deficiency to breathe, and it was difficult for the above oxygen to cool the wearer's face. This is because in the prior art, it was designed to supply a small amount of oxygen necessary for the wearer's breathing, so it was difficult to generate an air flow sufficient to enable cooling. In this prior art, when the amount of air supplied is increased to enable cooling, the inside of the front mask Pressure may become excessively high.

Registered Patent Publication No. 10-1887165 (Announcement Date: 2018.09.06.) Registered Patent Publication No. 10-1758652 (Announcement Date: 2017.07.17.) Public Patent Publication No. 10-2023-0024522 (Publication date: 2023.02.21.)

The present invention is intended to solve the problems of the prior art described above, and its purpose is to provide a mask having a cooling means that enables cooling of the entire face of the wearer. Furthermore, another purpose is to ensure visibility by removing moisture accumulated on the viewing window or glasses of the front mask, if necessary.

The present invention relates to a mask equipped with a cooling means, comprising: a mask body 200 in contact with the wearer's face and having a viewing window 210 formed on the front; a cooling air injection unit 112 formed on a predetermined portion of the mask body 200 to introduce cooling air into the space between the mask body and the wearer's face; A tube 120 connected at one end to the cooling air injection unit 112 and positioned between the mask body 200 and the wearer's face; A plurality of spray nozzles 121 formed on the tube 120 to spray cooling air into the space between the mask body and the wearer's face; and a cooling air discharge unit 110 for discharging the cooling air sprayed through the spray nozzle 121 to the outside of the mask.

A tube fixture 113 is formed in the cooling air discharge unit 110, and the tube 120 is inserted into the tube fixture 113 so that its position within the mask can be fixed.

Furthermore, the cooling air injection unit 112 is rotatably coupled to the mask body 200, and the arrangement state of the tube is changed by the tube position adjustment lever 123 formed on the cooling air injection unit 112. You can do it.

In another embodiment, the cooling air injection unit 112 is connected to a plurality of tubes 120 through a switching valve 114, and is operated by the switching valve 114 among the plurality of tubes 120. Cooling air supplied through the cooling air injection unit 112 may flow to the selected one.

The tube 120 is arranged to surround the wearer's face, and the cooling air sprayed from the plurality of spray nozzles 121 is sprayed from multiple directions toward the wearer's face.

The mask equipped with a cooling means according to the present invention supplies cooling air through a tube in which a plurality of spray nozzles are formed at predetermined intervals, enabling effective cooling of the entire face of the wearer. Furthermore, by providing a separate cooling air outlet that can discharge cooling air to the outside in addition to the breathing exhaust port, it is possible to prevent the pressure inside the front mask from being excessively high due to cooling air. Furthermore, it is possible to control the cooling area (wearer's face, glasses, viewing window) by providing a plurality of tubes to supply cooling air and selecting them as needed.

Figure 1 shows a full face mask according to the prior art.
2 to 4 show the overall structure of a mask according to the first embodiment of the present invention.
Figure 5 shows the cooling air outlet.
6 and 7 show the configuration of the cooling means according to the first embodiment.
Figure 8 shows the configuration of a cooling means according to the second embodiment.
9 and 10 show the configuration of a cooling means according to the third embodiment.
Figure 11 shows the configuration of a cooling air supply.

Hereinafter, the overall configuration of the mask equipped with a cooling means according to the present invention will be described with reference to the drawings. The specific structural or functional descriptions presented in the embodiments of the present invention are merely illustrative for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described in this specification, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

2 to 4 show the overall configuration of a mask equipped with cooling means according to an embodiment of the present invention. A viewing window 210 is formed on one side of the mask body 200, which forms the overall structural framework of the full-face mask, and an exhaust portion 310 is formed at the bottom of the viewing window 210 to discharge the wearer's exhaled breath to the outside. On both sides of the exhaust unit 310, purification cylinders 320 are provided to filter dust, smoke, gas, vapor, etc. and supply purified air to the inside of the front mask (space between the mask and the face). In addition, a fixing strap 400 is provided at a certain part of the mask body 200 to secure the full-face mask to the wearer's head. Since the above configuration is not different from a conventional full-face mask, further detailed description will be omitted. Furthermore, a film unit 600 may be further provided, which is an element that rolls and stores a transparent film covering the front of the viewing window 210 in a roll form. A film is wound in the form of a roll on the film portions 600 provided at both ends of the viewing window 210. If a contaminant is attached to the film covering the viewing window 210, turning the rotary lever 610 removes the contaminated film. It is separated from the viewing window 210 and wound on a roll, and the clean film wound in the form of a roll is positioned in front of the viewing window 210.

Furthermore, glasses 700 may be provided on the back of the viewing window 210, that is, inside the front mask. Preferably, the glasses 720 are attached to the articulated glasses holder 710 to adjust the position of the glasses 720. It is possible to adjust it. 1 to 3, it can be seen that the mask body 200 is provided with a cooling air outlet 110, which will be described in detail later.

Figure 5 shows the cooling air discharge unit 110, which is an element for discharging cooling air supplied inside the front mask to the outside of the front mask. Preferably, it may be composed of an outlet body 110b having a movement path for air to pass through and a cover 110a covering it. A through passage through which air passing through the outlet body 110b can pass is formed in a predetermined portion of the cover 110a. The outlet body 110b may be fixedly installed in a through hole formed in the mask body. Preferably, a tube fixture 113 for fixing a tube supplying cooling air may be integrally formed. The cooling air discharge unit 110 is intended to prevent the pressure inside the front mask from being excessively high due to cooling air. When the pressure inside the front mask is not high, that is, when cooling air is not supplied, external contaminated air is discharged. It is desirable that the front mask be sealed so that air does not enter the inside. Therefore, it is better to install a valve in the cooling air discharge unit 110 to control the flow of air. It is possible for the user to install a manual valve that operates manually as needed, but preferably, the check valve opens when the inside of the front mask is above a predetermined pressure and can be closed when the inside of the front mask is below a predetermined pressure. It is desirable to be provided.

Figure 6 shows a cooling means 100 according to the first embodiment of the present invention. The cooling air injection unit 112 and the cooling air discharge unit 110 are installed through a predetermined portion of the mask body 200. A tube 120 is inserted into one end of the cooling air injection unit 112, and the tube 120 is fixed to the tube fixture 113 to determine its position inside the front mask. Preferably, the tube fixture 113 is formed integrally with the cooling air discharge unit 110, so that assembly and installation can be simplified. Cooling air supplied from the outside of the front mask through the cooling air injection unit 112 flows along the tube 120. A plurality of spray nozzles 121 capable of spraying air flowing within the tube 120 to the outside of the tube 120 may be formed on the tube 120 at predetermined intervals. Therefore, the cooling air supplied through the cooling air injection unit 112 is supplied into the front mask through the plurality of spray nozzles 121. And most of the cooling air supplied into the front mask through the plurality of injection nozzles 121 is discharged through the cooling air discharge unit 110, and a small amount of cooling air is discharged to the outside through the breathing exhaust unit 310. It can be. The arrangement of the tube 120 can be variously modified as needed by adjusting the position of the tube process tool 113 and the length of the tube 120. Preferably, it will be good for cooling efficiency if the spray nozzle 121 formed on the tube 120 is directed toward the wearer's face. However, if sprayed directly toward the wearer's eyes, it may interfere with vision, so it is best to avoid the direction toward the wearer's eyes. FIG. 7 shows the relative positional relationship between the cooling means 100 and the glasses unit 700, and the air sprayed from the spray nozzle 121 forms a haze inside the glasses and the viewing window 210 of the glasses unit 700. It can also be used to remove moisture. Therefore, once a full-face mask is worn, it is impossible to wipe sweat or glasses, but when wearing a mask according to the present invention, sweat can be prevented and moisture can be prevented from accumulating on glasses and viewing windows, greatly increasing work efficiency. You can.

Figure 8 shows the configuration of the cooling means 100 according to the second embodiment of the present invention. The cooling air injection unit 112 is rotatably coupled to the mask body 200, and a tube position adjustment lever 123 may be formed on a portion of the cooling air injection unit 112. The wearer can hold the tube position adjustment lever 123 and rotate it little by little in the front and rear direction, and thus the arrangement method of the tube 120 can be changed. Also, if the arrangement method of the tube 120 changes, the position and direction of the spray nozzle 121 also changes, so the wearer can change the part directly contacted by the cooling air by rotating the tube position control lever 123. You can. In other words, it was normally set so that the cooling air directly touches the forehead, but if a problem occurs with moisture accumulating in the glasses, the arrangement of the tube 120 and the spray nozzle 121 is changed to allow the air to directly contact the glasses. This makes it possible to remove moisture at a rapid rate.

Figure 9 shows the configuration of the cooling means 100 according to the third embodiment of the present invention. In the third embodiment, two or more tubes 120a and 120b are used, and the cooling air supplied through the cooling air injection unit 112 flows along one of the two tubes 120a and 120b according to the wearer's selection. It flows. For example, the spray nozzle 121a of the first tube 120a is formed close to the glasses and the viewing window to remove moisture from the glasses and the viewing window, and the spray nozzle 121b of the second tube 120b cools the wearer's face. For this purpose, it can be formed close to the wearer's forehead or head. That is, as shown in FIG. 9, the arrangement method of the spray nozzle installed on the first tube 120a and the spray nozzle installed on the second tube 120b may be different depending on the needs. The first tube 120a and the second tube 120b are connected to the cooling air injection unit 112 through a switching valve 114, and the wearer rotates the switching lever 114c of the switching valve 114. It is possible to control whether to supply cooling air to the first tube 120a or the second tube 120b.

Figure 10 shows the configuration of the switching valve 114, in which the rotating body 114b is rotatably coupled to the switching valve housing 1140a. Inside the rotating body 114b, a flow path through which cooling air supplied through the cooling air injection unit 112 can flow is formed, and the end of the flow path is formed in a portion spaced apart from the rotation center of the rotating body 114b. It is done. And a plurality of valve outlets 114d connected to the first tube 120a and the second tube 120b are formed in the switching valve housing 114a, and the end of the flow path formed in the rotating body 114b is connected to the first tube (120a). It is possible to determine the tube through which cooling air flows depending on whether it is connected to the valve outlet 114d coupled with 120a) or the valve outlet 114d coupled with the second tube 120b.

Figure 11 shows a cooling air supply 130. Compressed oxygen cylinders can be used for cooling air, but using compressed oxygen cylinders may make it difficult to use them for a long time. The cooling air supplier 130 can be attached to the wearer's waistband, etc., and the purification tank 320 can be coupled to the socket formed on the cooling air supplier 130. The air flowing into the cooling air supply 130 through the purification tank 320 flows through the fan 132 and is discharged to the outside of the cooling air supply 130 through the cooling air outlet 134. do. The cooling air outlet 134 and the cooling air inlet 112 of the front mask may be connected through a tube. Preferably, a temperature control means 133 such as a Peltier element is provided inside the cooling air supply 130, and the purified air can be cooled or heated and supplied through the purification tank 320. Here, management/maintenance costs can be reduced by using the same purification tank 320 as the purification tank 320 used in the front mask.

100: cooling means 110: cooling air outlet
110a: Cover 110b: Outlet body
112: Cooling air inlet
113: tube fixture 114: changeover valve
114a: changeover valve housing 114b: rotating body
114c: switching lever 114d: valve outlet
120: Tube 121: Spray nozzle
123: Tube position control lever
130: Cooling air supplier 131: Purification bottle socket
132: fan 133: temperature control means
134: Cooling air outlet
200: mask body 210: viewing window
310: exhaust unit 320: purification tank
400: fixing strap
600: Film unit 610: Rotating lever
700: Glasses unit 710: Articulated glasses holder
720: Glasses

Claims (5)

Relating to a mask with cooling means,
A mask body 200 that is in contact with the wearer's face and has a viewing window 210 on the front;
a cooling air injection unit 112 formed in a predetermined portion of the mask body 200 to introduce cooling air into the space between the mask body and the wearer's face;
A tube 120 connected at one end to the cooling air injection unit 112 and positioned between the mask body 200 and the wearer's face;
A plurality of spray nozzles 121 formed on the tube 120 to spray cooling air into the space between the mask body 200 and the wearer's face; and
It includes a cooling air discharge unit 110 for discharging the cooling air sprayed through the spray nozzle 121 to the outside of the mask,
The cooling air injection unit 112 is rotatably coupled to the mask body 200, and the arrangement of the tube is changed by a tube position adjustment lever 123 formed on the cooling air injection unit 112. A mask equipped with a cooling means.
The method of claim 1, wherein a tube fixture 113 is formed in the cooling air discharge unit 110, and the tube 120 is inserted into the tube fixture 113 to fix the position within the mask. Mask with means.
delete The method according to claim 1 or 2, wherein the cooling air injection unit 112 is connected to a plurality of tubes 120 through a switching valve 114,
A mask equipped with cooling means, wherein cooling air supplied through the cooling air injection unit 112 flows through one of the plurality of tubes 120 selected by the operation of the switching valve 114.
The method according to claim 1 or 2, wherein the tube 120 is arranged in a shape that surrounds the wearer's face, and the cooling air sprayed from the plurality of spray nozzles 121 is sprayed from multiple directions toward the wearer's face. A mask with cooling means as featured.