Abstract:
Disclosed herein is a cooling device such as a blind head cooling helmet which will fully cover the head contour plus the area of the eyes, cheeks, and ears, having an lid arrangement with internal air ducts. An air pump generates and pushes small volumes of slow pace moving air, so that it be transferred to the blind head cooling helmet via an “C” shaped tube, to all the internal air duct, and finally escaping through the bottom of the lid arrangement, not without before the resulting air bubbles crashing against some areas of the internal layer creating a therapeutic effect or relaxing comfort to areas of the face.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     Not Applicable 
     FEDERALLY SPONSORED RESEARCH 
     Not Applicable 
     SEQUENCE LISTING OR PROGRAM 
     Not Applicable 
     FIELD OF THE INVENTION 
     The present invention relates to a head cooling device generally and in particular to a new full head contour cooling hat or head cooling helmet for controlling body temperature and relieving headache symptoms caused by various conditions such as migraines, sinusitis, head contusions or concussions or fever. 
     DESCRIPTION OF RELATED PRIOR ART 
     Due to the fact that the human head is very susceptible to the common headaches, migraine, sinusitis, head contusions, fever, and many other aches, it is sometimes necessary to decrease the abnormal temperatures and or discomforts produced by said aches. Artificial means such as the old water-ice bag, cold and hot therapies products, etc. have been used to alleviate these symptoms. 
     There have been prior attempts in the art in the form of similar cooling devices to decrease the abnormal temperatures and/or produce the cooling effect when applied on the human head, but none have been designed to cover other regions of the human head, such as the cheeks, ears and eyes. An example of said prior art we can find disclosed is in U.S. Pat. No. 5,957,964, issued Sep. 28, 1999 to Ceravolo. A cooling helmet is provided to cover the head contour, however, said invention does not cover the area of the eyes, cheeks and ears. U.S. Pat. No. 5,957,964 to Ceravolo also discloses the use of water to apply a cold effect as does the present invention, but it does not have the presence of permanent pockets filled with gel, or another semisolid-colloid materials, attached to its internal layer with empty cavities in association with permanent hollow water pockets attached to its parallel external layer with magnets, which provides both a cooling effect and pain relief therapy. Also, the present invention, unlike U.S. Pat. No. 5,957,964 to Ceravolo, discloses an air duct to carry small volumes of air to the interior of the blind head cooling helmet for the production of air bubbles, that will hit the layers, plus provide for the circulation of the water contained therein. Other patents describe some of the features used by Ceravolo, or other applications but none disclose the novel aspects of the present invention. The only patent that resembles the present invention is disclosed in U.S. D529,617, issued October 2006 to the present Inventor. 
     While the aforementioned prior art provide mechanisms to reduce body temperatures, none of them provide a device comprising a blind head cooling helmet or hat that covers all head contours to reduce body temperature and alleviate various aches while providing a therapeutic effect for the user. 
     Therefore, what is needed is a blind head cooling helmet that can cover all the contours of the head including the eyes, ears and cheeks to help resolve the need in the art. Problem. The implementation of small magnets adapting into small empty cavities, plus the circulation of the liquid medium by slow aeration produces a therapeutic effect in addition to a cooling effect to better serve this long felt need in the art. 
     SUMMARY OF THE INVENTION 
     The present invention solves the above references problems by providing a simple, efficient and practical device that helps reduce and/or decrease fever, aches, or discomforts produced by abnormal body temperatures and or headaches while also providing a therapeutic effect for the user. To achieve the foregoing and other advantages, the present invention, briefly described, provides a lightweight head cooling device such as a blind head cooling helmet that fits easily on the human head without the use of any elastic fastener or other means. 
     A preferred embodiment of the invention comprises a cooling device such as a blind head cooling helmet which comprises an external and internal layer joined in common edges resulting in the creation of a main hollow cavity that will be filled with water and/or other liquid medium to provide a cooling effect. 
     It is another aspect of the invention, to provide a cooling device such as a blind head cooling helmet with permanent hollow water pockets comprising at lease one small magnet permanently attached to its internal ceiling, both logistically located in the external layer to provide indirect contact to specific face muscles in order to specifically target discomfort and/or pain in said specific areas of the face. 
     Also, the present invention discloses a cooling device such as a blind head cooling helmet with pockets filled with gel and/or another colloid permanently attached to its internal layer with its respective empty cavities in order to further increase the cooling effect. The present invention also provides for the user to depress the water pockets comprising the magnet to allow the coupling or adaptation of the magnets with its respective water pockets from the external layer into the empty cavities of the gel pockets of the internal layer which helps alleviate pain and aches, while producing a therapeutic effect. 
     Another aspect of the present invention provides a cooling device such as a blind head cooling helmet that comprises an air pump for picking up small volumes of air and causing said small volumes of air to slowly move into a separate air line that will connect to the lid arrangement of the blind head cooling helmet to the interior cavity through a flexible air tube that will plug into the principal air line which will transport the small slow paced moving air from the air pump, sending it to an inverted “Y” shaped air tube to parallel perforated tubes finally joining in a common point or duct. The perforated tubes provide the slow paced moving air several points of escape through the perforated cavities in route to the top of the main hollow cavity or lid-lid base bottom, causing the air bubbles to crash against the areas that cover the eyes, cheeks, ears, etc, on the wet surface of the internal layer already comprising the liquid medium, which in a preferred embodiment comprises water, in order to produce a massage like sensation for alleviating discomfort and aches at the different areas of the face. In order for the bubbles to be released from said perforated tubes, another aspect of the invention comprises a lid arrangement with at least one internal small vertical tube for allowing the escape of the air produced from the resulting air bubbles. 
     In another embodiment of the present invention the cooling device comprises a lid arrangement with at least one small compartment for attaching, at least one watch, which in a preferred embodiment comprises a solar watch, to get track of the time when the blind head cooling helmet is placed inside the refrigerator, or for tracking the time said device has been worn by user. 
     Further, another aspect of the present invention comprises pins made up of at least one of flexible-elastic pins or shock absorbers, that will permanently support and separate the external layer of the blind head cooling helmet from the internal layer of said blind head cooling helmet, while at the same time providing an extended elasticity which produces a massage like effect when the water, or liquid medium circulates through its interior. 
     An advantage of the present invention is that the cooling device, such as a blind head cooling helmet comprises flexible and elastic materials which make it easy to wear and remove. Since it is designed to cover the eyes, cheeks and ears, it will not fall or slip away causing it to be securely adapted to the user&#39;s head. 
     A further advantage of the present invention is that the cooling device such as a blind head cooling helmet comprises a removable flexible thermometer, which in a preferred embodiment of the invention is located on of the forehead of the blind head cooling helmet, so that the user can track the temperature of the blind head cooling helmet inside any household appliance or simple cooling apparatus. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The preferred embodiments of the invention will herein after be described in conjunction with the included drawings, which are provided only by way of illustration and not in limitation of the invention, and that various modifications may be made thereto without departing from the spirit of the invention as claimed, wherein like designations denote like elements, and in which; 
         FIG. 1A  shows a view of a gel pocket  36  with its respective empty cavity  37  where its internal walls  36   a , floor  36   b ,  31   a , and external walls  36   c  can be seen. 
         FIG. 1B  shows a top view of the different forms and sizes of the gel pockets  36  with its respective hollow cavities  37 . 
         FIG. 2A  shows a front view of an air pump  10  for picking up air from the exterior of the blind head cooling helmet and transferring it to the blind head cooling helmet via a long air line  11  for connecting it to the lid arrangement  FIG. 2B  and  FIG. 2G , with its air-outlet  10   a , its electrical cord  10   b , its plug  10   c  and its air-inlet portion  10   d.    
         FIG. 2B  shows a cross sectional view of the lid arrangement containing the lid  20 , the small square compartment  20   a  for the small digital watch  25 , not illustrated here, and the top mouth  20   d  of the vertical air tube  20   b  and its bottom mouth  20   e , plus the long air line  11 , the air-inlet  12  of the air tube, which in a preferred embodiment comprises a “C” shaped air tube, its body  13 , and its air-out outlet  14  portion. 
         FIG. 2C  shows a top view of the lid  20 , the small square compartment  20   a  for the watch, not illustrated here, and the top portion  20   d  of the vertical tube  20   b.    
         FIG. 2D  shows a inclined view of the long vertical air tube  20   b  with its small round grates  20   c  in its interior, plus the top mouth  20   d  and its bottom end  20   e  portion. 
         FIG. 2E  shows a top view of the small multi perforated rounded grate  20   c  by where the released air will escape. 
         FIG. 2F  shows an inclined view of the small rounded grate  20   c  of  FIG. 2B ,  FIG. 2C ,  FIG. 2D  and  FIG. 2E . 
         FIG. 2G  shows a left side view of the blind head cooling helmet with the lid arrangement  FIG. 2B  with the rest of the air duct arrangement that includes the first submerged air tube  15  connecting to the inverted “Y” air tube  16 , and the air tubes  17   a ,  17   b , and perforated tubes  18   a ,  18   b ,  18   c ,  18   d  and  18   e.    
         FIG. 2H  and  FIG. 2I  shows a enlarged view of the air tubes  17   a ,  17   b , and perforated tubes  18   a ,  18   b ,  18   c ,  18   d  and  18   e  with its respective holes  19  and its body  22 . 
         FIG. 3A  shows another cross-sectional view of the lid arrangement  FIG. 2B  but with the internal shock absorbers  32  being centrally penetrated  28  by the first submerged air tube  15  plus the external layer  30  and the internal layer  31 . 
         FIG. 3B  shows an enlarged view of the lid arrangement  FIG. 2B  and the description explained in  FIG. 2B ,  FIG. 2G  and  FIG. 3A . 
         FIG. 3C  shows another enlarged view of principal air duct  15  centrally fortified by the shock absorbers  32 , plus the external layer  30  and its parallel internal layer  31  and the suggested presence of the liquid water  35  in between. 
         FIG. 3D  shows a front view of the central hole  28  of the shock absorber  32  by where the principal air line  15  will pass through. 
         FIG. 4A  shows an enlarged cross section view of the first taken (normal) position of one hollow water pocket  38  with its hanging magnet  26  facing down its respective parallel empty cavity  37  of the pertaining gel pocket  36 , plus the shock absorbers  32  separating the respective external layer  30  and the internal layer  31 . 
         FIGS. 4B-4G  show cross section views of the water pockets  38  as being depressed or actuated by user in order to cause the magnet  26  to adapt to the parallel empty cavity  37  of the gel pockets  36 . 
         FIG. 4H  shows an enlarged cross section view of the water pocket-magnet arrangement coupling inside its parallel gel pockets arrangement. 
         FIG. 5  shows a left side view of the blind head cooling helmet with its lid arrangement  FIG. 2B  at the top  1   g , a dome-like harder plastic  27 , and covered forehead  1   d , left side  1   e   2 , left ear  1   c   2 , left eye  1   a   2 , left cheek  1   b   2  and back  1   f.    
         FIG. 6  shows a left side view of the air ducts described in  FIG. 2G ,  FIG. 2H  and  FIG. 2I . 
         FIG. 7  shows a left side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, with the gel pockets  36  and its respective empty cavities  37 . 
         FIG. 8  shows  FIG. 7  in solid lines. 
         FIG. 9  shows a left side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, with the empty cavities  37  of its respective gel pockets  36  being overlapped or adapted in with its respective parallel water pockets  38  and magnets  26 , not seen in this drawing, where each one will be fully described in the Detailed Description of the Preferred Embodiment. 
         FIG. 10  shows  FIG. 9  in solid lines. 
         FIG. 11  shows a left side view of the blind head cooling helmet solely with the external surface  30  described in  FIG. 5  and with the external dry surfaces of the water pockets  38  and its respective tops or peaks  39  (dry roof  26   a  of the magnet  26 ). 
         FIG. 12  shows the front side view of the blind head cooling helmet with the lid base  21 , its air-inlet  12 , the thermometer  75  on the forehead  1   d  and covered top  1   g , right side  1   e   1 , left side  1   e   2 , right eye  1   a   1 , left eye  1   a   2 , right cheek  1   b   1  and left cheek  1   b   2  where are the surface is the external layer  30 . 
         FIG. 13  shows a front view of the air duct arrangement (or intermediate skeleton), seen in  FIG. 2G ,  FIG. 3A ,  FIG. 3B  and  FIG. 6 , and the perforated air ducts seen in  FIG. 2H  and  FIG. 2I . 
         FIG. 14  shows another front side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, as seen in  FIG. 7 , with the gel pockets  36  and its respective empty cavities  37 , where each one will be fully described in the Detailed Description of the Preferred Embodiment. 
         FIG. 15  shows the same  FIG. 14  but the lines are solid. 
         FIG. 16  shows the front side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, as seen in  FIG. 9 , with the empty cavities  37  of its respective gel pockets  36  being overlapped or adapted in with its respective parallel water pockets  38  and magnets  26 . 
         FIG. 17  shows  FIG. 16  in solid lines. 
         FIG. 18  shows a front view of the blind head cooling helmet with its external surface  30 , as described in  FIG. 11 , with the external dry surfaces of the water pockets  38  and its respective tops or peaks  39  (dry roof  26   a  of the magnet  26 ). 
         FIG. 19  shows the back side view of the blind head cooling helmet described in  FIG. 5  and  FIG. 12  with the top  1   g , fore back  1   f  and covered left side  1   e   2 , right side  1   e   1 , left ear  1   c   2  and right ear  1   c   1 . 
         FIG. 20  shows the back side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, as seen in  FIG. 7  and  FIG. 14 , with the gel pockets  36  and its respective empty cavities  37 . 
         FIG. 21  shows  FIG. 20  in solid lines. 
         FIG. 22  shows the back side view of the blind head cooling helmet, with the internal layer  31  in dashed lines, as seen in  FIG. 9  and  FIG. 16 , with the empty cavities  37  of its respective gel pockets  36  being adapted to the respective parallel water pockets  38  and magnets  26  not seen in this drawing. 
         FIG. 23  shows  FIG. 22  in solid lines. 
         FIG. 24  shows a back view side of the blind head cooling helmet with its external surface  30  described in  FIG. 11  and  FIG. 18 , with the external dry surfaces of the water pockets  38  and the respective tops or peaks  39  (dry roof  26   a  of the magnet  26 ). 
         FIG. 25  shows the top side view of the blind head cooling helmet described in  FIG. 5 ,  FIG. 12  and  FIG. 19  with the fore back  1   f  and covered forehead  1   g , left side  1   e   2 , right side  1   e   1 , left eye  1   a   2 , right eye  1   a   1 , left ear  1   c   2  and right ear  1   c   1 . 
         FIG. 26  shows a top side view of the blind head cooling helmet, in dashed lines, with the internal layer as seen in  FIG. 7 ,  FIG. 14  and  FIG. 20 , with the gel pockets  36  and its respective empty cavities  37 . 
         FIG. 27  shows  FIG. 26  in solid lines. 
         FIG. 28  shows a top view of the blind head cooling helmet, with the internal layer  31  in dashed lines, as seen in  FIG. 9  and  FIG. 16  and  FIG. 22 , with the empty cavities  37  of its respective gel pockets  36  being overlapped or adapted in with its respective parallel water pockets  38  and magnets  26 , not seen in this drawing. 
         FIG. 29  shows  FIG. 28  in solid lines. 
         FIG. 30  shows a top view of the blind head cooling helmet with its external surface described in  FIG. 11 ,  FIG. 18  and  FIG. 24 , with the external dry surfaces of the water pockets  38  and its respective tops or peaks  39  (dry roof  26   a  of the magnet  26 ). 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     This specification and the accompanying figures disclose the preferred embodiment as example of the invention. The drawings illustrated in the figures are not to scale and are only intended to serve as illustrating examples of the invention. The invention is not intended to be limited to the embodiment illustrated. Numerous modifications, changes, variations, substitutions and equivalents will be apparent to those skilled in the art without departing from the spirit and scope of the present invention. 
     Referring now to  FIG. 1A  and  FIG. 1B  the gel pockets  36  with its respective empty cavities  37 , where the gel pockets are filled with enclosed gel or other colloid material, and its permanently attached to the internal layer  31 ,  31   a  not seen in this figure, of the blind head cooling helmet. Every pocket is made of flexible resistant elastic materials, such at least one of plastic, rubber, etc, so as to not produce any discomfort on the human head area were they are located. The gel pockets have an external wall  36   c  and at least one empty space or cavity  37  with internal walls  36   a , internal floor  36   b ,  31   a  and top surface  37   a . The gel pockets will be surrounded by liquid water and they will be selectively positioned around the entire contour of the blind head cooling helmet. The gel pockets have different sizes and shapes. Eventually every single empty space  37  will be adapted to its respective and parallel water pockets  38  and magnets  26 , not seen in this drawing. 
     Disclosed in  FIG. 2A  is an air pump with a body  10 , an electrical cord  10   b , a plug  10   c , and an outlet  10   d  to pick up the air. Said pump  10  will generate small volumes of air and send it at slow pace into a separated flexible long air line  11 , which as defined by inventor in this specification is referred to as intermediate skeleton, that will be plugged to the lid configuration  FIG. 2B  of the blind head cooling helmet, transferring the slow moved air into the exterior mouth  12  of the flexible air tub  13 , which in a preferred embodiment comprises a “C” shaped air tube for allowing it to be transferred to its end portion  14  finally entering in another air duct  15 , not seen in this drawing.  FIG. 2C  shows the top view of the lid  20  with one small square compartment  20   a  to temporally allocate a watch  25 , which in a preferred embodiment comprises a solar powered digital watch, not seen in this drawing. 
     The lid  20  has in its interior at least one small vertical hollow tube  20   b , as seen in  FIG. 2B  and  FIG. 2D  with a top portion  20   d , wherein the air from the interior of the blind head cooling helmet will escape to the exterior of the blind head cooling helmet through its bottom portion  20   e , where the air from the interior of the blind head cooling helmet will enter, and finally at least one small rounded  20   c  net  FIG. 2D ,  FIG. 2E  and  FIG. 2F , that will allow the air to escape but at the same time avoid the water to escape. The size of the vertical tubes can vary in width to facilitate the entrance and escape through its hollow interior. 
       FIG. 2G  shows the blind head cooling helmet with the entire air duct arrangement, also referred to by the inventor as the intermediate skeleton, that includes the first submerged air tube  15  connecting to the inverted “Y” air tube  16 , and the air tubes  17   a ,  17   b , and the perforated air tubes  18   a ,  18   b ,  18   c ,  18   d  and  18   e  which will cause the slow pace moving air to escape in the form of air bubbles as shown in  FIG. 2H  and  FIG. 2I . 
       FIG. 6  shows a left side view of the entire air duct arrangement or intermediate skeleton. 
       FIG. 13  is a front side view of the entire air duct arrangement or the intermediate skeleton. 
       FIG. 3A ,  FIG. 3B ,  FIG. 3C  and  FIG. 3D  show the pins or shock absorbers  32 , which in a preferred embodiment comprise a material such as at least one of flexible elastic material that will be attached to the external layer  30  and the internal layer  31 , keeping them together and creating a main hollow cavity in between where the liquid water  35  or another liquid medium will be enclosed to produce the cooling effect. The shock absorbers will be selectively positioned or located around the entire contour of the blind head cooling helmet but will not be covering the central surfaces or roofs of the gel pockets  38 , not seen in this drawing, except some areas of the top central gel pocket  40 , also not seen in this drawing. Only the shock absorbers that are located from the forehead area to the inverted “Y” air tube are centrally hollow  FIG. 3D  to contain the passage of the first submerged air tube  15  connecting to the inverted “Y” air tube  16 , but the remaining shock absorbers are solid and made up of at least one of a flexible or elastic material. 
     The external layer  30  has an external dry surface  30   a  in contact with the air and its internal surface  30   b  will be wet when in contact with water  35 ; its parallel internal layer  31  has an external surface  31   a  which is wet when in contact with the water but its internal dry surface  31   b  will be dry and in direct contact with the human head&#39;s skin when the blind head cooling helmet is on. 
       FIG. 4A  to  FIG. 4F  shows the elasticity of the water pocket  38  when user presses down the roof  39  of the water pocket into its respective parallel empty cavity of its gel pocket  36  and coupling configuration. When the water pocket is slowly actuated its near external layer  30  also will be pulled down with it at the same time.  FIG. 4A  shows the normal shape and form of the water pocket when it is not actuated by user. When user releases the water pocket it reverts automatically to its original form and shape  FIG. 4A . It is called water pocket because this hollow dome-like feature is in direct contact with the water from the main hollow cavity. The idea of this process is to proportionate a soft pressure or massage-like effect with the small magnet  26  attached in the ceiling of the water pocket over the floor  36   b  (the same external surface  31   a  of the internal layer  31 ) of the empty cavity. It is believed that magnets are capable of producing therapeutic effects in humans. Plus,  FIG. 4G  and  FIG. 4H  are enlarged cross section views of  FIG. 4A  and  FIG. 4F . 
       FIG. 5 ,  FIG. 12 ,  FIG. 19  and  FIG. 25  show the blind head cooling helmet, where the lid  20  is attached to the lid, by any attachable means such as at least one of screws, Velcro, etc., down into its lid base  21 , that is built onto a dome-like harder elastic plastic  27 , so the lid will not make contact with the top of the internal layer touching the human head. The blind head cooling helmet comprises a forehead  1   d  section, a back  1   f , a right side  1   e   1 , a left side  1   e   2 , the covered right eye  1   a   1  and left eye  1   a   2 , the covered right ear  1   c   1  and left ear  1   c   2 , and the covered right cheek  1   b   1  and left cheek  1   b   2 . 
     A thermometer  75  is located on the forehead  1   d  section of the blind head cooling helmet, which in a preferred embodiment comprises a small flexible and comfortable digital thermometer. Said thermometer is removable and attached to the blind head cooling helmet. In a preferred embodiment of the invention the thermometer uses liquid crystal technology to indicate the temperature of the blind head cooling helmet when it is storage inside the refrigerator to allow the water to cool. It may use a dyed red alcohol instead of the toxic mercury. 
       FIG. 7 ,  FIG. 14 ,  FIG. 20  and  FIG. 26  show the internal layer  31 , in dashed lines, of the blind head cooling helmet with the gel pockets  36  with its respective empty cavities  37  together. In a preferred embodiment, the left side of  FIG. 7  shows the right forehead gel pocket  41   b  with its respective empty spaces  71   b ,  72   b ; the left ocular gel pocket  42   b  have only one empty cavity  73   b , the left cheek gel pocket  43   b  have one cavity  74   b , the left mid side gel pocket  44   b  have three empty spaces  67   b ,  68   b  and  69   b ; the left ear gel pocket  45   b  have only one cavity  70   b ; the left-back bottom gel pocket  46   a  have its empty cavity  66   a ; the left mid back gel pocket  47   a  have its empty space  65   a , the left upper back gel pocket  48   a  have also three cavities  62   a ,  63   a  and  64   a , but the top central gel pocket  40  have not any empty space.  FIG. 7  shows the shock absorbers  32 . 
       FIG. 9 ,  FIG. 16 ,  FIG. 22  and  FIG. 28  show the internal layer  31 , in dashed lines, of the blind head cooling helmet with the water pocket-magnet arrangement  38 ,  26  overlapping its respective parallel gel pocket-empty cavity arrangement  36 , 37  at the same time. In a preferred embodiment, in  FIG. 9 , the left side view of the blind head cooling helmet, water pocket-magnet arrangement  58   b  will adapt into its parallel gel pocket-empty cavity arrangement  71   b ,  41   b ; water pocket-magnet arrangement  59   b  will adapt into its parallel gel pocket-empty cavity arrangement  72   b ,  41   b ; water pocket-magnet arrangement  60   b  will adapt into its parallel gel pocket-empty cavity arrangement  73   b ,  42   b ; water pocket-magnet arrangement  61   b  will adapt into its parallel gel pocket-empty cavity arrangement  74   b ,  43   b ; water pocket-magnet arrangement  54   b  will adapt into its parallel gel pocket-empty cavity arrangement  67   b ,  44   b ; water pocket-magnet arrangement  55   b  will adapt into its parallel gel pocket-empty cavity arrangement  68   b ,  44   b ; water pocket-magnet arrangement  56   b  will adapt into its parallel gel pocket-empty cavity arrangement  69   b ,  44   b ; water pocket-magnet arrangement  53   a  will adapt into its parallel gel pocket-empty cavity arrangement  66   a ,  46   a ; water pocket-magnet arrangement  52   a  will adapt into its parallel gel pocket-empty cavity arrangement  65   a ,  47   a ; water pocket-magnet arrangement  49   a  will adapt into its parallel gel pocket-empty cavity arrangement  62   a ,  48   a ; water pocket-magnet arrangement  50   a  will adapt into its parallel gel pocket-empty cavity arrangement  63   a ,  48   a ; and finally the water pocket-magnet arrangement  51   a  will adapt into its parallel gel pocket-empty cavity arrangement  64   a ,  48   a.    
       FIG. 16 , shows the front side view of the blind head cooling helmet, water pocket-magnet arrangement  58   a  will adapt into its parallel gel pocket-empty cavity arrangement  71   a ,  41   a ; water pocket-magnet arrangement  59   a  will adapt into its parallel gel pocket-empty cavity arrangement  72   a ,  41   a ; water pocket-magnet arrangement  60   a  will adapt into its parallel gel pocket-empty cavity arrangement  73   a ,  42   a ; water pocket-magnet arrangement  61   a  will adapt into its parallel gel pocket-empty cavity arrangement  74   a ,  43   a ; water pocket-magnet arrangement  58   b  will adapt into its parallel gel pocket-empty cavity arrangement  71   b ,  41   b ; water pocket-magnet arrangement  59   b  will adapt into its parallel gel pocket-empty cavity arrangement  72   b ,  41   b ; water pocket-magnet arrangement  60   b  will adapt into its parallel gel pocket-empty cavity arrangement  73   b ,  42   b ; water pocket-magnet arrangement  61   b  will adapt into its parallel gel pocket-empty cavity arrangement  74   b ,  43   b ; water pocket-magnet arrangement  55   a  will adapt into its parallel gel pocket-empty cavity arrangement  68   a ,  44   a ; water pocket-magnet arrangement  55   b  will adapt into its parallel gel pocket-empty cavity arrangement  68   b ,  44   b  water pocket-magnet arrangement  57   a  will adapt into its parallel gel pocket-empty cavity arrangement  70   a ,  45   a ; and finally the water pocket-magnet arrangement  57   b  will adapt into its parallel gel pocket-empty cavity arrangement  70   b ,  45   b.    
       FIG. 22 , shows the back side view of the blind head cooling helmet, water pocket-magnet arrangement  49   a  will adapt into its parallel gel pocket-empty cavity arrangement  62   a ,  48   a ; water pocket-magnet arrangement  50   a  will adapt into its parallel gel pocket-empty cavity arrangement  63   a ,  48   a ; water pocket-magnet arrangement  51   a  will adapt into its parallel gel pocket-empty cavity arrangement  64   a ,  48   a ; water pocket-magnet arrangement  52   a  will adapt into its parallel gel pocket-empty cavity arrangement  65   a ,  47   a ; water pocket-magnet arrangement  53   a  will adapt into its parallel gel pocket-empty cavity arrangement  66   a ,  46   a ; water pocket-magnet arrangement  49   b  will adapt into its parallel gel pocket-empty cavity arrangement  62   b ,  48   b ; water pocket-magnet arrangement  50   b  will adapt into its parallel gel pocket-empty cavity arrangement  63   b ,  48   b ; water pocket-magnet arrangement  51   b  will adapt into its parallel gel pocket-empty cavity arrangement  64   b ,  48   b ; water pocket-magnet arrangement  52   b  will adapt into its parallel gel pocket-empty cavity arrangement  65   b ,  47   b ; water pocket-magnet arrangement  53   b  will adapt into its parallel gel pocket-empty cavity arrangement  66   b ,  46   b ; water pocket-magnet arrangement  56   b  will adapt into its parallel gel pocket-empty cavity arrangement  69   b ,  44   b ; water pocket-magnet arrangement  56   a  will adapt into its parallel gel pocket-empty cavity arrangement  69   a ,  44   a ; the covered ears portion are not seen in this drawing. 
       FIG. 28 , shows the top side view of the blind head cooling helmet, is the same detailed explanation in  FIG. 9 ,  FIG. 16  and  FIG. 22 . 
       FIG. 11 ,  FIG. 18 ,  FIG. 24  and  FIG. 30  shows the external layer  30 ,  30   a  of the blind head cooling helmet with the water pocket-magnet arrangement  38 ,  26  located in specific and determined areas. The external layer  30  comprises is a solid layer, this will be the real view ornamentally seen of the blind head cooling helmet but if the external layer  30  is manufactured of transparency basis all the internal layer  31  and its features will be also seen through. 
     It is understood that the preceding descriptions, explanations, and illustrations are given merely by way of illustration and not in limitation of the invention and that various modifications or embodiments may be made without departing from the spirit and scope of the invention as claimed.