Apparatus for making hexagonal and pentagonal molecular structure water

A hexagonal and pentagonal molecular structure water making apparatus includes an upper water reservoir disposed at a predetermined portion of the refrigerating chamber of the refrigerator, a hexagonal and pentagonal molecular structure water generating section for generating hexagonal and pentagonal molecular structure water by electrolysis of water from the upper water reservoir, a hexagonal and pentagonal molecular structure water storing section for storing hexagonal and pentagonal molecular structure water generated at the hexagonal and pentagonal molecular structure water generating section, and a freezing container for storing hexagonal molecular structure water after receiving water stored at the hexagonal molecular structure water storing reservoir of the hexagonal molecular structure water storing section through a connecting pipe. The hexagonal and pentagonal molecular structure water have useful effects for preventing adult diseases.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an apparatus for making hexagonal and 
pentagonal molecular structure water, and more particularly to separately 
supplying hexagonal molecular structure water and pentagonal molecular 
structure water. 
2. Description of the Prior Art 
Conventionally, water is classified into hexagonal water and pentagonal 
water based on its molecular structure, as shown in FIGS. 2A to 2C. Each 
type of water having these structures has a different effect on the human 
body when taken. The hexagonal molecular structure water, as shown in FIG. 
2A, is well known to have effects in prevention of some adult diseases 
such as cancer, constipation, diabetics, and gastroenteric disorders. The 
pentagonal molecular structure water, as shown in FIG. 2C, is well known 
to have good effects for skin care and the prevention of skin disease. 
Meanwhile, the water molecular structure described above can be rearranged 
by the change of ions dissolved in the water. For example, Lithium(Li), 
Sodium(Na), Calcium(Ca), Strontium(Sr), Silver(Ag), and Zinc(Zn) may cause 
the water structure to change into the hexagonal molecular structure 
water. In addition, Potassium(K), Rubidium(Ru), Magnesium(Mg), 
Aluminum(Al), Chlorine(Cl) and Cesium(Cs) break the hexagonal molecular 
structure and create a pentagonal molecular structure. 
There, so far, is no known the apparatus which can make the common 
molecular structure water into hexagonal or pentagonal molecular structure 
water, except for methods of just cooling or freezing the water. 
Referring to FIG. 1, reference numeral 1 indicates a body of a 
refrigerator. 
On the front surface of the refrigerator 1, a freezing chamber door 5 and a 
refrigerating chamber door 6 are engaged with an upper hinge 2, a middle 
hinge 3, and a lower hinge 4, respectively. 
Reference numeral 8 indicates a quick freezing chamber with an ice 
container(not shown), which is disposed inside the freezing chamber 7. 
Conventionally, the ice generated in the ice container with common water 
like faucet water can be available for use, but it has not been good for 
the health care. 
SUMMARY OF THE INVENTION 
Accordingly, it is an object of the present invention to provide an 
apparatus for making hexagonal molecular structure water and pentagonal 
molecular structure water by means of ions generated by the electrolysis 
of water. 
It is another object of the present invention to provide a freezing 
apparatus of hexagonal molecular structure water, useful for the human 
body, by means of the electrolysis of water when making the ice in the 
refrigerator. 
For achieving the objecting of the present invention it includes an upper 
water reservoir disposed at a predetermined portion of the refrigerating 
chamber of the refrigerator, a hexagonal and pentagonal molecular 
structure water generating section for generating hexagonal and pentagonal 
molecular structure water by electrolysis of water from the upper water 
reservoir, a hexagonal and pentagonal molecular structure water storing 
section for storing hexagonal and pentagonal molecular structure water 
generated at the hexagonal and pentagonal molecular structure water 
generating section, and a freezing container for storing hexagonal 
molecular structure water after receiving water stored at the hexagonal 
molecular structure water storing reservoir of the hexagonal molecular 
structure water storing section through a connecting pipe.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring to FIG. 3, there is shown a refrigerator with hexagonal and 
pentagonal molecular structure water apparatus according to a first 
embodiment of the present invention. 
In the drawing, reference numeral 100 indicates a refrigerator body. On the 
front surface of the refrigerator body 100, a freezing chamber door 90 and 
a refrigerating chamber door 95 are engaged with hinges 93 and 94, 
respectively. 
The refrigerator body 100 is divided into two chambers, i.e., a freezing 
chamber 30 and a refrigerating chamber 80. A freezing container 10, with a 
connecting pipe 20 at one portion of the left inside of the freezing 
chamber 30, is disposed inside the freezing chamber 30. Inside the 
refrigerating chamber 80, an upper water reservoir 40, a hexagonal and 
pentagonal molecular structure water generating section 50, and a 
hexagonal and pentagonal molecular structure water storing section 60 are 
disposed in order from the top. 
Referring to FIG. 4, there is shown an enlarged freezing container 10 of 
FIG. 3. The freezing container 10 is shaped like a top opened box. A right 
angled connecting pipe 20 is disposed at one portion of the wall 11 of the 
freezing container 10. A plate(not shown) with a plurality of small boxes, 
for making a desired ice shape, is disposed inside the freezing container 
10. 
Referring to FIG. 5, there is shown an enlarged upper water reservoir 40 
disposed at one portion of the refrigerating chamber 40, which is provided 
with a lid 43 for receiving water and an exhausting section 45 disposed at 
the bottom thereof. 
FIG. 6 shows the exhausting section 45 in details. In the drawing, there 
are shown a hollow cock support 45b, a T-shaped cock 45a inserted into the 
upper water reservoir 40 through the cock support 45b, a spring 46 
disposed between a lower space of the cock 45a and a corner of the lower 
protrusion 45c, and a lid 48 integrally formed with a plurality of ribs 
45d connected with the cock support 45b. The lid 48 is threadedly coupled 
with a lower surface of the upper water reservoir 40. Reference numeral 47 
in FIG. 6 indicates an outlet for discharging water through the fibs 45d. 
Meanwhile, the hexagonal and pentagonal molecular structure water 
generating section 50, shaped like a top opened box, includes a pushing 
protrusion 59 for pushing and opening the cock 45a, a plate-shaped filter 
52 disposed at an intermediate position thereof, and a positive pole plate 
55 and a negative pole plate 51 disposed at both walls of the hexagonal 
and pentagonal molecular structure water generating section 50. In 
addition, a hexagonal molecular structure water path 53 and a pentagonal 
molecular structure water path 54 are respectively disposed at each bottom 
thereof. The positive pole plate 55 and negative pole plate 51 are 
connected with the microcomputer(not shown), respectively, with a supply 
of direct current of 12 V. 
FIG. 8 shows a hexagonal and pentagonal molecular structure water storing 
section 60. In the drawing, a separating plate 65 is disposed at an 
intermediate position of the hexagonal and pentagonal molecular water 
storing section 60 for separating into the hexagonal and pentagonal 
molecular structure water, respectively. By disposing the separating plate 
65, the pentagonal molecular structure water storing reservoir 65 is 
formed at the left side thereof and the hexagonal molecular structure 
water storing reservoir 67 is formed at the right side thereof. A pump 68 
and a motor 68a are disposed at a predetermined portion of the connecting 
pipe 20, which is disposed at one portion of the hexagonal molecular 
structure water reservoir 67, for enabling the hexagonal molecular 
structure water in the hexagonal molecular structure water reservoir 67 to 
flow into the freezing container 10 through the connecting pipe 20. In 
addition, a tap-shaped hexagonal molecular structure water valve 69a and a 
tap-shaped pentagonal molecular structure water valve 69b are disposed at 
a predetermined lower portion of the front wall of the hexagonal molecular 
structure water storing reservoir 67 and the pentagonal molecular 
structure water storing reservoir 66. 
From now on, the operation of the first embodiment will be explained. 
In a state that a lid 43 is opened, the mineral water or desired water is 
supplied into the upper water reservoir 40. The upper water reservoir is 
disposed on the hexagonal and pentagonal molecular structure water 
generating section 50. A center of the cock 45a of the exhausting section 
45, disposed at the lower portion of the upper water reservoir 40, is 
fixed to be placed on the pushing protrusion 59, so that the cock 45a of 
the exhausting section 45 is opened and then the water flows into the 
hexagonal and pentagonal molecular water structure generating section 50. 
The water which flows in a direction of the positive pole plate 55 of the 
hexagonal and pentagonal molecular structure water generating section 50 
becomes hexagonal molecular structure water by means of the electrolysis 
of water and the water which flows in a direction of the negative pole 
plate 51 of the hexagonal and pentagonal molecular structure water 
generating section 50 also becomes pentagonal molecular structure water by 
means of the electrolysis of water. 
At this time, for making the ice of the hexagonal molecular water structure 
water, the water of hexagonal molecular structure flows into the hexagonal 
molecular structure water storing reservoir 67 through the hexagonal 
molecular structure water path 53, and by means of the pump 68, disposed 
at the connecting pipe 20, driven by the motor 68a, hexagonal molecular 
structure water flows into the freezing container 10 through the 
connecting pipe 20. The hexagonal molecular structure water is frozen 
therein thereby obtaining the hexagonal molecular structure water. 
In addition, the hexagonal molecular structure water in the hexagonal 
molecular structure water storing container 67 is available for the user 
to drink. The pentagonal molecular structure water in the pentagonal 
molecular structure water storing container 66 is also available for user 
to drink. 
Referring to FIG. 9, there is shown an apparatus for making the hexagonal 
and pentagonal molecular structure water according to the second 
embodiment of the present invention. 
First, in comparison with the first embodiment of the present invention, 
which is utilizing the freezing chamber 30 for achieving the object of the 
invention, the second embodiment of the present invention utilizes only 
the refrigerating chamber 80, with reference to FIG. 3. 
In FIG. 9, reference numeral 97 indicates a cabinet of the hexagonal and 
pentagonal molecular structure water making apparatus. 
In an tipper inside portion of the cubic-shaped cabinet 97 is disposed a 
water reservoir support 87. On the water reservoir support 87 is placed 
the upper water reservoir 40 with the lid 43. A permanent magnet 75 with a 
hollow path 76 is disposed below the upper water reservoir 40. The 
hexagonal and pentagonal molecular structure water generating section 50a 
is disposed below the permanent magnet 75 for making the hexagonal and 
pentagonal molecular structure water and separating the water into two 
parts of the hexagonal molecular structure water and the pentagonal 
molecular structure water. 
Meanwhile, a structure of the exhausting section 45 disposed at the lower 
portion of the upper water reservoir 40 is similar to one of the first 
embodiment of the present invention, except for its reversed location, so 
the description thereof is not provided. 
The permanent magnet 75 for stabilizing the structure of water is disposed 
around the left and right side of the path 76 between the hexagonal and 
pentagonal molecular structure water generating section 50a of the upper 
water reservoir 40. As shown in FIG. 10, the permanent magnet 75 is 
disposed in the form of alternate disposition of South and North poles 
thereof. A pushing protrusion 59 for pushing and opening the cock 45a 
shown in FIG. 6 is disposed at the path 76 in an inwardly protruded form. 
FIG. 11 shows the water reservoir support 87 for supporting the upper water 
reservoir 40. A supporting plate 88 with a semi-circular groove is 
disposed inside the water reservoir support 87. The upper water reservoir 
40 is inserted into and supported to the supporting plate 88. The water 
reservoir support 87 and the supporting plate 88 is preferably made of the 
plastic materials, but possibly made of the steel plate. The hexagonal and 
pentagonal molecular structure water generating section 50a, as shown in 
FIG. 12, in a shape of the upper portion opened is disposed with the 
ventilating plate 96 having a function of the filter in a horizontal 
direction and with the plate-shaped filter 52 in a vertical direction. 
Thus, the ventilating plate 96 and the filter 52 are disposed inside the 
hexagonal and pentagonal molecular structure water generating section 50a 
so that they cross each other. The plate-shaped positive pole plate 55 and 
the plate-shaped negative pole plate 51 are disposed at the top of the 
ventilating plate 96 predetermingly apart from the filter 52 by a 
predetermined space. The filter 52 functions to pass the positive and 
negative ions therethrough, and the negative pole plate 51 and positive 
pole plate 55 activate for generating the positive or negative ions. 
Meanwhile, the pentagonal molecular structure water storing reservoir 66 is 
disposed below the ventilating plate 96 of the side of the positive pole 
plate 55 for storing the pentagonal molecular structure water, and the 
hexagonal molecular structure water storing reservoir 67 is disposed below 
the ventilating plate 96 of the side of the negative pole plate 51 for 
storing the hexagonal molecular structure water. The pentagonal molecular 
structure water valve 69b is disposed at a front surface of the pentagonal 
molecular structure water storing reservoir 66, and the hexagonal 
molecular structure water valve 69a is disposed at a front surface of the 
hexagonal molecular structure water storing reservoir 67. 
As shown in FIGS. 9 and 13, a ventilating plate 96a with a plurality of 
holes 85 for supporting the cup 77 and preventing water's splashing, is 
horizontly disposed at the intermediate position of the waterspout 
container 86. The water in the waterspout container 86 is later evaluated 
by the user. 
As the apparatus for making the hexagonal and pentagonal molecular 
structure water is described above, it can be dispose inside the freezing 
chamber of the refrigerator, in addition it is also available to dispose 
separately from the refrigerator. 
The operation of the second embodiment of the present invention will be 
explained. 
In a state that the lid 43 is opened, the mineral water or desired water is 
supplied into the upper water reservoir 40. The upper water reservoir 40 
is disposed at the hexagonal and pentagonal molecular structure water 
generating section 50. The center of the cock 45a of the exhausting 
section 45, disposed at the lower portion of the upper water reservoir 40, 
is placed on the pushing protrusion 59, so that the cock 45a of the 
exhausting section 45 is opened and then the mineral water or desired 
water flows downwardly. At this time, as the water stored in the upper 
water reservoir 40 flows along the path 76, the structure of water is 
stabilized by means of the permanent magnet 75. At this time, the 
stabilization means used to decrease the molecular structure of water for 
better conditions for making hexagonal molecular structure water through 
the means of ions. After that, the positive ions in the water gather to 
the negative pole plate 51 and the negative ions in the water gather to 
the positive pole plate 55. The negative pole plate 51 and the positive 
pole plate 55 are respectively connected to a microcomputer(not shown) and 
applied with a direct current of 12 V. 
Meanwhile, the hexagonal molecular structure water generated by means of 
the electrolysis at the hexagonal molecular structure water generating 
reservoir 83 is stored in the hexagonal molecular structure water storing 
reservoir 67 and the pentagonal molecular structure water generated at the 
pentagonal molecular structure water generating reservoir 82 is stored in 
the pentagonal molecular structure water storing reservoir 66. By opening 
the hexagonal molecular structure water valve 69, a user may obtain the 
hexagonal molecular structure water, and by opening the pentagonal 
molecular structure water valve 9b, the pentagonal molecular structure 
water may be available. In addition, the splashing water is gathered at 
the waterspout container 86 through the holes 85. 
The third embodiment of the present invention will be explained. 
Referring to FIG. 14, it is replaced the freezing container disposed at the 
freezing chamber of the first embodiment is replaced with the affixing 
frame having the freezing container. In the drawing, reference numeral 12 
indicates an affixing frame to be disposed at the left of the freezing 
chamber 30 shown in FIG. 3. The freezing container 10a in the affixing 
frame 12 is detachably disposed. 
The affixing frame 12, as shown in FIG. 14, is disposed with the 
plate-shaped negative pole plate 51 and the plate-shaped positive pole 
plate 55 at the bottom thereof. The insulator 15 is disposed between the 
two pole plates 51 and 55. A plurality of electric poles 51a and 55a are 
disposed at the front side of the two pole plates 51 and 55, respectively, 
and connected with a power supply cable (not shown). 
The freezing container 10a, as shown in FIGS. 15 and 16, is disposed with 
the hexagonal molecular structure water ice generating section 67a and the 
pentagonal molecular structure water ice generating section 66a at both 
sides thereof. The ion box and the filter are disposed between two ice 
generating sections 67a and 66a, and supported by means of the support 19. 
In the third embodiment of the present invention, only one ion box and one 
filter 19 are shown, but it is possible to use a plurality of the ion 
boxes and filters. 
The operation of the hexagonal and pentagonal molecular structure water 
freezing apparatus according to the third embodiment of the present 
invention will be explained. 
After filling the freezing container 10a with mineral water or desired 
water, it is needed to insert the freezing container 10a into the affixing 
frame 12. When the power is supplied to the negative pole plate 51 and the 
positive pole plate 55 through the electric poles 51a and 55a, by means of 
the electric charge, the positive ions of the water gather to the negative 
pole plate 51 and the negative ions of the water gather to the positive 
pole plate 55. By receiving the hexagonal molecular structure water 
therefrom, and then the hexagonal molecular structure ice is made at the 
hexagonal molecular structure ice generating section 67a of the freezing 
container 16. By receiving the pentagonal molecular structure water 
therefrom, and then the pentagonal molecular structure ice is made at the 
pentagonal molecular structure ice generating section 66a of the freezing 
container 16. 
As described above, the hexagonal and pentagonal molecular structure water 
generating apparatus according to the present invention provides the 
effect of separating the water into two types of ions and generating the 
hexagonal molecular structure water and the pentagonal molecular structure 
water by means of the electrolysis of water, which are useful for the 
human body. The hexagonal molecular structure water freezing apparatus of 
the present invention also provides a fresh hexagonal molecular structure 
ice, which are also useful for human body when it is taken.