TWI692310B - Sparkling water maker and pressure bottle - Google Patents

Abstract

A sparkling water maker is provided. The sparkling water maker includes a pressure bottle and an inflating mechanism. The pressure bottle includes a first receiving body, a first connecting seat, a first blocking plug, a first pressing member, a valve member, a second blocking plug, a second pressing member, a rotary releasing pressure element, an upper positioning element, a gas guiding element, a lower positioning element, and a water plug. In addition, the inflating mechanism includes a second connecting seat, an upper interposer, a lower interposer and an air bottle.

Description

Bubble water machine and pressure bottle

The invention is a bubble water machine and a pressure bottle, in particular, only a bubble water machine and a pressure bottle with a valve element and a rotary pressure relief element.

Please refer to FIG. 1. FIG. 1 is a cross-sectional view of the first accommodating groove 2181 and the first pressure relief component 219 of the bubble water dispenser of Taiwan Patent I618514. The first accommodating groove 2181 is provided with a first pressure relief component 219 The first pressure relief component 219 includes a first screw connection element 2191, a first abutment element 2192 and a first spring element 2193. The first pressure relief component 219 is used to remove excess gas and help release the bubble water machine Internal pressure. However, the syrup of the liquid 8 easily adheres to the first spring element 2193, so it is not easy for the user to clean the first pressure relief element 219. Moreover, the pressure that the first pressure relief assembly 219 can withstand cannot be adjusted. Therefore, how to improve the problem of the above-mentioned Taiwan patent I618514 bubble water machine is worth considering for those with ordinary knowledge in the art.

The purpose of the present invention is to provide a sparkling water machine that can adjust the internal pressure to which the upper pressure bottle is subjected, and the user can easily clean all components of the upper pressure bottle. The bubble water machine of the present invention includes a pressure bottle and an inflation mechanism. The pressure bottle includes a first receiving body, a first connecting seat, a first air blocking plug, a first pressure applying element, a valve element, a second air blocking plug, a second pressure applying element, a rotary release The pressure element, an upper positioning element, a gas guiding element, a lower positioning element, and a water plug. Wherein, the bottom of the first receiving body includes an upper end screw connection portion and a lower end screw connection portion. The first connecting seat is screwed to the upper end of the first receiving body. The first connecting seat includes a first pressure relief area, and the first pressure relief area includes a first air release channel. The bottom of the first air blocking plug covers the first bleed passage, and the top end of the first air blocking plug is embedded in the first pressure applying element. The valve element is screwed into the first pressure relief area, the valve element includes a second air release channel and a valve screw connection, and the valve element abuts against the first pressure applying element. The bottom of the second air blocking plug covers the second air release channel, and the top end of the second air blocking plug is embedded in the second pressure applying element. The rotary pressure relief element is screwed to the valve screw connection portion, the rotary pressure relief element includes a third air release channel, and the rotary pressure relief element abuts against the second pressure applying element. The upper positioning element is screwed on the upper screw connection. The gas guiding element is arranged in the upper positioning element, and the bottom of the gas guiding element has a balanced pressure applying structure. The lower positioning element is screwed to the lower end screw connection portion, and the lower positioning element includes a first intake passage. The balanced pressure structure abuts the top of the water plug, and the bottom of the water plug covers the first air intake channel. In addition, the inflation mechanism includes a second connecting seat, an upper intermediary element, a lower intermediary element, and an inflation bottle. The lower end of the first receiving body is engaged with the second connecting base, and the second connecting base includes at least one cylindrical block. The upper intermediary element includes a second air intake channel and at least one first accommodating groove. The second air intake channel communicates with the first air intake channel, and a cylindrical block is embedded in the first accommodating groove. The lower intermediary element is connected to the upper intermediary element, and the lower intermediary element includes a third intake passage, and the third intake passage communicates with the second intake passage. The inflation bottle includes a jet line, and the jet line is embedded in the third air intake channel. In the bubble water machine described above, the downward pressure of the valve element against the first pressure element is less than the downward pressure of the rotary pressure relief element against the second pressure element. In the bubble water machine described above, the pressure bottle further includes a top cover, the top cover includes an air release switch and a top cover air blocking plug, the air release switch abuts on the top of the top cover air blocking plug, and the The first connection seat further includes a top cover vent channel; when the vent switch is closed, the top cap vent plug covers the top cap vent channel; when the vent switch is turned on, the cap vent plug cannot cover Hold the top cover vent channel. In the bubble water machine described above, the valve element further includes a stagnation space, which surrounds the second bleed passage. In the bubble water machine described above, the gas guide element further includes a plurality of guide channels, the guide channels are arranged in a radial manner, and the lengths of the guide channels are different from each other. Another object of the present invention is to provide a pressure bottle that can adjust the internal pressure it bears, and the user can easily clean all components of the pressure bottle. The pressure bottle of the present invention includes a first receiving body, a first connecting seat, a first air blocking plug, a first pressure applying element, a valve element, a second air blocking plug, a second pressure applying element and A rotating pressure relief element. The bottom of the first receiving body includes an upper end screw connection portion and a lower end screw connection portion. The first connecting seat is screwed to the upper end of the first receiving body. The first connecting seat includes a first pressure relief area, and the first pressure relief area includes a first air release channel. The bottom of the first air blocking plug covers the first air release channel. The top end of the first air blocking plug is embedded in the first pressure applying element. The valve element is screwed into the first pressure relief area, the valve element includes a second air release channel and a valve screw connection, and the valve element abuts against the first pressure applying element. The bottom of the second air blocking plug covers the second air release channel. The top end of the second air blocking plug is embedded in the second pressure applying element. The rotary pressure relief element is screwed to the valve screw joint, the rotary pressure relief element includes a third air release channel, and the rotary pressure relief element abuts against the second pressure applying element. In the pressure bottle described above, the downward pressure of the valve element against the first pressure element is less than the downward pressure of the rotary pressure relief element against the second pressure element. The pressure bottle mentioned above also includes an upper positioning element, a gas guiding element, a lower positioning element and a water stopper. The upper positioning element is screwed on the upper screw connection. The gas guiding element is arranged in the upper positioning element, and the bottom of the gas guiding element has a balanced pressure applying structure. The lower positioning element is screwed to the lower end screw connection portion, and the lower positioning element includes a first intake passage. In addition, the balanced pressure structure abuts the top of the water plug, and the bottom of the water plug covers the first air intake passage. In the above-mentioned pressure bottle, wherein the valve element further includes a stagnation space, the stagnation space surrounds the second bleed passage. The above-mentioned pressure bottle further includes a top cover, the top cover includes a bleed switch and a top cover air blocking plug, the bleed switch abuts the top of the top cover air blocking plug, and the first connection seat It also includes a top cover vent channel; when the vent switch is closed, the top cap vent plug covers the top cap vent channel; when the vent switch is turned on, the top cap vent plug cannot cover the top cap Vent channel. In order to make the above-mentioned features and advantages of the book more comprehensible, preferred embodiments are described below in conjunction with the accompanying drawings, which are described in detail below.

Please refer to FIG. 2, FIG. 3A, FIG. 3B and FIG. 3C, FIG. 2 is a perspective view of the bubble water machine 3 of this embodiment, FIG. 3A is a front view of the bubble water machine 3, and FIG. 3B is shown. FIG. 3A is an AA sectional view of the bubble water machine 3, and FIG. 3C is an enlarged view of the portion X marked in FIG. 3B. The sparkling water machine 3 of this embodiment includes a pressure bottle 4 and an inflation mechanism 5. Wherein, the pressure bottle 4 includes a top cover 40, a first accommodating body 41, a first connecting seat 42, a first air blocking plug 43, a first pressure applying element 431, a valve element 44, and a second blocking Gas plug 45, a second pressure applying element 451, a rotary pressure releasing element 46, an upper positioning element 47, a gas guiding element 48 (please refer to FIG. 3D, which shows the gas guiding element 48 at different angles Perspective view), a lower positioning element 49 and a water plug 490. Wherein, the first accommodating body 41 is used for accommodating a liquid 8, for example, drinking water, beverages containing sugar additives or alcoholic beverages. Please refer to FIG. 3E. FIG. 3E is a cross-sectional view of the top cover 40. The top cover 40 includes a bleed switch 401 and a top cover air blocking plug 402. The bleed switch 401 is against the top of the top cover air blocking plug 402 . In addition, please refer to FIG. 3C again and FIG. 3F at the same time. FIG. 3F is a perspective view of the first connecting base 42. The first connecting seat 42 is screwed to the upper end of the first accommodating body 41. The first connecting seat 42 includes a first pressure relief area 420 and a cap vent channel 422, and the first pressure relief area 420 includes a first气气槽421. When the bleed switch 401 is closed, the top cover plug 402 covers the top cover bleed passage 422 to prevent the gas of the pressure bottle 4 from leaking out. After that, please refer to FIG. 3G. FIG. 3G is a schematic diagram when the bleed switch 401 is turned on. When the bleed switch 401 is turned on, the top cover plug 402 cannot completely cover the top cover bleed passage 422. In this way, the bleed switch 401 can help the pressure bottle 4 to release some gas first and release the pressure. Therefore, when the user opens the top cover 40, he can avoid being hit by a large gas pressure. In addition, the bottom of the first air blocking plug 43 covers the first bleed passage 421, and the top of the first air blocking plug 43 is embedded in the first pressure element 431 (please refer to FIG. 3H, which is shown as FIG. 3H (The first air blocking plug 43 is embedded in the first pressure element 431 and is located in different perspective views). Please refer to FIG. 3C again and FIG. 3I at the same time. FIG. 3I is a perspective view of the valve element 44 at different angles. The valve element 44 is screwed into the first pressure relief area 420. The valve element 44 includes a second air release passage 441 1. A valve screw connection 442 and a stagnation space 443, and the valve element 44 abuts the first pressure element 431 downwards, so the first pressure element 431 can drive the first air blocking plug 43 to close the first一gas channel 421. In addition, when the internal pressure of the first accommodating body 41 is too high, the first pressure element 431 and the first air blocking plug 43 cannot resist the upward pressure of the gas or liquid 8, and the first air blocking plug 43 cannot be completely closed住第一气气槽421. Therefore, excess gas or a little liquid 8 can flow from the first bleed passage 421 into the stagnation space 443 and the second bleed passage 441. Please refer to FIG. 3J. FIG. 3J depicts a perspective view of the second air blocking plug 45 embedded in the second pressure element 451 at different angles. The bottom of the second air blocking plug 45 covers the second vent channel 441, and the second The top end of the air blocking plug 45 is embedded in the second pressure applying element 451. Please refer to FIG. 3C again and FIG. 3K at the same time. FIG. 3K is a perspective view of the rotary pressure relief element 46 at different angles. The rotary pressure relief element 46 is screwed to the valve screw connection portion 442. The rotary pressure relief element 46 includes a first Three bleed passages 461, and when the rotary pressure relief element 46 and the valve element 44 are fully tightened, the rotary pressure relief element 46 provides maximum downward pressure to drive the second pressure applying element 451 down. Therefore, the second pressure applying element 451 also makes the second air blocking plug 45 tightly close the second bleed passage 441. In addition, when the gas inside the first containing body 41 has entered the second bleed passage 441, the second air blocking plug 45 will be pressed by the gas to open the second pressure element 451 upward, and the second air blocking plug 45 will Change to the conductive state. Then, the gas is released to the outside of the bottle via the third bleed passage 461. Therefore, the rotary pressure relief element 46, the second air blocking plug 45, and the second pressure applying element 451 can remove excess gas and help release pressure, so the internal pressure of the first housing 41 can be maintained in a stable state. Compared with the conventional first pressure relief assembly 219, as long as the rotary pressure relief element 46 is disassembled in this embodiment, the rotary pressure relief element 46, the second air blocking plug 45 and the second pressure applying element 451 are very easy to clean. Syrup is also not easy to adhere to the above components. In the above, when the rotary pressure relief element 46 and the valve element 44 are fully tightened, the downward pressure of the valve element 44 against the first pressure applying element 431 is less than that of the rotary pressure relief element 46 against the second The downward pressure of the pressure member 451. In other words, the force that the second air blocking plug 45 closes the second bleed passage 441 is stronger than the force that the first air blocking plug 43 closes the first bleed passage 421. In this way, when the internal pressure of the first housing body 41 is large, the first air blocking plug 43 cannot prevent the gas inside the first housing body 41 from being blocked, but the second air blocking plug 45 can still prevent the gas from going out Channeling. Moreover, after a period of time, the internal pressure formed by the stagnation space 443 and the second bleed passage 441 will also be equal to the internal pressure of the first housing 41 (the pressure in the two areas is balanced). In this way, the first air blocking plug 43 can return to the original position, preventing the gas or liquid 8 in the first housing 41 from being blocked. In addition, if the pressure bottle 4 is placed sideways or upside down, the liquid 8 overflowing from the second bleed passage 441 will also flow toward the periphery of the valve element 44 so that the liquid 8 will be concentrated in the stagnation space 443, At this moment, the stagnation space 443 functions like a small sump. Therefore, the liquid 8 is also less likely to overflow from the second bleed passage 441 to the rotary pressure relief element 46 or from the third bleed passage 461 to the outside. In addition, since the rotary pressure relief element 46 is assembled to the valve element 44 in a screw connection, adjusting the tightness of the rotary pressure relief element 46 can simultaneously change the amount of pressure that the second air blocking plug 45 can withstand. In detail, when the rotation pressure relief element 46 is loosely tightened, the upward pressure that the second air blocking plug 45 can bear is small. Conversely, when the rotating pressure relief element 46 is tightened more tightly, the upward pressure that the second air blocking plug 45 can withstand is greater, and the gas cannot easily leak out. Therefore, adjusting the pressure of the pressure bottle 4 via the rotary pressure relief element 46 can also affect the taste of the sparkling water. Therefore, compared to the first pressure relief assembly 219 of Taiwan Patent I618514, the rotary pressure relief element 46 of this embodiment can adjust the second air blocking plug 45 (the second air blocking plug 45 can also remove excess gas and help release pressure ) The amount of pressure that can be withstood. In addition, please refer to FIG. 3D again, the gas guide element 48 is disposed in the upper positioning element 47 (please refer to FIG. 4C first), and the gas guide element 48 further includes a plurality of guide channels 481, which are arranged in an array Radial appearance, and the length of these diversion channels 481 are different. In this way, when the ejected gas passes through the gas guide element 48, the guide channel 48 can evenly distribute the gas (bubble in) into the first housing 41, and the bubble is evenly integrated into the liquid 8 Inside. In addition, it can avoid the accumulation of carbon dioxide in the water to form larger bubbles, thereby improving the dissolution rate of carbon dioxide. In addition, please refer to FIG. 3L, which is a perspective view of the gas guide element 48 of different types. In addition to the gas guide element 48 in the form shown in FIG. 3D, the gas guide element 48 shown in FIG. 3L can also help the gas (bubble in) to be evenly dispersed into the first receiving body 41. Please refer to FIGS. 4A, 4B, 4C and 4D. FIG. 4A shows a left side view of the bubble water machine 3, FIG. 4B shows a BB sectional view of the bubble water machine 3 in FIG. 4A, and FIG. 4C shows FIG. 4B is an enlarged view of the portion marked Y, and FIG. 4D is a cross-sectional view showing the bottom of the first receiving body 41 alone. The bottom of the first accommodating body 41 includes an upper end screw connection 41U and a lower end screw connection 41L, the upper positioning element 47 is screwed on the upper end screw connection 41U, and the lower positioning element 49 is screwed on the lower end screw connection 41L, and the lower positioning element 49 includes a first intake passage 491 (please refer to FIG. 4E, which is shown as a cross-sectional view showing the lower positioning element 49 alone). In addition, the bottom of the gas guiding element 48 has a balanced pressure structure 480 composed of a U-shaped plate structure 480U and an elongated plate structure 480L (see FIG. 3D), U-shaped Both the plate-shaped structure 480U and the strip-shaped plate structure 480L belong to an elastic body. Among them, the long plate-shaped structure 480L will abut the center of the top of the water plug 490, and the U-shaped plate-shaped structure 480U abuts the non-center of the top of the water plug 490. Therefore, when the water plug 490 is pushed downward by the balanced pressure structure 480, the bottom of the water plug 490 will cover the first intake passage 491 (see FIG. 4C and FIG. 4E). 4B and 4C again, the inflation mechanism 5 includes a second receiving body 50, a second connecting seat 51, an upper intermediary element 52, a lower intermediary element 53, an L-shaped linkage rod 54, a cylinder start switch 55. An inflatable bottle 56 and a lower covering shell 57 and an upper covering shell 58. The second accommodating body 50 covers the inflatable bottle 56, the lower end of the first accommodating body 41 is engaged with the second connecting seat 51, and the second connecting seat 51 includes at least one cylindrical block 51C. Please refer to FIGS. 4C and 4F. FIG. 4F is a perspective view of the upper intermediary element 52 at different angles. The upper intermediary element 52 includes a second intake passage 521, at least one first accommodating groove 522, and two pushing blocks 523, the second intake passage 521 communicates with the first intake passage 491, and the cylindrical block 51C of the second connecting seat 51 is embedded in the first receiving groove 522. Moreover, the bottom end of the upper intermediary element 52 further includes two symmetrical W-shaped structures 52W. In addition, please refer to FIGS. 4G and 4H. FIG. 4G is a cross-sectional view showing the lower intermediary element 53 alone, and FIG. 4H is a perspective view of the lower intermediary element 53 and the upper intermediary element 52. The lower intermediary element 53 is connected to the upper intermediary element 52. The lower intermediary element 53 includes a third air intake passage 531, and the third air intake passage 531 and the second air intake passage 521 communicate with each other (see FIG. 4C). Please refer to FIG. 5A, FIG. 5B, FIG. 5C, and FIG. 5D. FIG. 5A shows a perspective view of the L-shaped link 54 against the W-shaped structure 52W, and FIG. 5B shows the upper intermediary element 52 driving the L-shaped. A perspective schematic view of the downward movement of the linkage rod 54. FIG. 5C is a schematic diagram of the L-shaped linkage rod 54 passing through the lower cladding housing 57. FIG. 5D is a perspective view of the lower cladding casing 57. Wherein, one end of the L-shaped link lever 54 is against the W-shaped structure 52W, and the other end of the L-shaped link lever 54 is connected to the cylinder start switch 55. In addition, please refer to FIG. 4B again, the inflation bottle 56 includes a cylinder thimble 56N and a jet line 56P, and one end of the jet line 56P is embedded in the third air intake channel 531 of the lower intermediary element 53. In addition, please refer to FIGS. 5C and 5D again. The lower cladding shell 57 is located below the upper intermediary element 52, and part of its volume has covered the upper intermediary element 52. The lower cladding shell 57 has two symmetrical The straight bar-shaped through hole 571 is formed, and the L-shaped link rod 54 passes through the two straight bar-shaped through holes 571 described above. In this way, the L-shaped link lever 54 can only move up and down linearly in the straight through hole 571. When the pressure bottle 4 is rotated by the user, the first accommodating body 41 will rotate the upper intermediary element 52 to rotate. After that, the upper intermediary element 52 will drive the L-shaped linkage rod 54 to move downward. In detail, before the upper intermediary element 52 rotates, the L-shaped linkage rod 54 is originally at the uppermost end of the W-shaped structure 52W. After the upper intermediary element 52 is rotated, the L-shaped linkage rod 54 will move down to approach the W-shape At the bottom end of the structure 52W (please refer to FIG. 5B again). Furthermore, since the L-shaped link lever 54 is restricted by the movement of the straight through hole 571, the L-shaped link lever 54 moves straight down. After that, when the L-shaped link lever 54 moves downward, the L-shaped link lever 54 will also pull down the cylinder activation switch 55 so that the cylinder activation switch 55 touches the cylinder ejector pin 56N (please refer to FIG. 5B again). In this way, the gas in the inflation bottle 56 will be injected to the third intake passage 531 through the jet line 56P, and the gas will be transmitted to the second intake passage 521 through the third intake passage 531 (please refer to FIG. 4C again) ). After that, please refer to FIG. 4C again, and the gas is transmitted to the first intake passage 491 via the second intake passage 521. After that, the water plug 490 will be pressed by the gas to open the balance pressure structure 480 upward, so the first intake passage 491 will be turned into a conductive state. Then, the gas is transferred to the gas guide element 48 through the first intake passage 491. After that, the gas is dispersed into the liquid 8 evenly. In this way, the liquid 8 that has received the gas will be converted into sparkling water, a sparkling beverage containing sugar additives or an alcoholic sparkling beverage, and the gas will drive the liquid 8 to impact the top cover 40 upwards, so the liquid 8 (sugar or alcoholic sparkling beverage) will not rush down into the inflation mechanism 5. In addition, the linkage design of the present invention via the L-shaped linkage rod 54 results in that the inflatable bottle 56 of the sparkling water machine 3 is favorably disposed on the side of the pressure bottle 4, so if the volume of the inflatable bottle 56 is too large, it will not cause sparkling water The overall height of the machine 3 is too high. Therefore, the gas bottle 56 can store more gas (carbon dioxide). Please refer to FIGS. 4C, 4G, and 4H again. The lower intermediary element 53 further includes at least one pressure relief component 532 (three pressure relief components 532 are used as examples in this embodiment). The pressure relief component 532 includes a second accommodating groove 5321, a screwing element 5322, an abutting portion 5323 and a spring element 5324, the second accommodating groove 5321 includes a vent hole 5321H. The screw connection element 5322 is screwed to one end of the second receiving groove 5321, and the screw connection element 5322 includes a through hole 5322H. In addition, the abutting portion 5323 is accommodated in the other end of the second accommodating groove 5321, and one end of the spring element 5324 abuts the screwing element 5322, and the other end of the spring element 5324 abuts the abutting portion 5323, The abutment portion 5323 closes the vent hole 5321H via the elastic force of the spring element 5324. As such, when too much gas is ejected from the gas injection line 56P (when the inflation bottle 56 releases too much gas), the multiple pressure relief components 532 can remove excess gas from the through hole 5322H to help release the pressure. Please refer to FIG. 4C, FIG. 6A and FIG. 6B again. FIG. 6A shows a perspective view of the upper cladding housing 58 at different angles. FIG. 6B shows the upper intermediary element 52 assembled inside the upper cladding housing 58. Schematic. The upper covering casing 58 is provided with at least one feedback component 580 (in this embodiment, there are four feedback components 580). The feedback component 580 includes a spring abutting block 581 and a feedback spring element 582, the spring abutting block 581 One part is embedded in the feedback spring element 582. The pushing block 523 is disposed between the two spring abutting blocks 581. When the upper intermediary element 52 drives the L-shaped link rod 54 to move downward, the pushing block 523 simultaneously pushes the left or right spring against the block 581. At the same time, the spring abutment block 581 presses the feedback spring element 582, so that the feedback spring element 582 generates a return elastic force. Afterwards, the returned elastic force will force the upper intermediary element 52 to return to the original position. Therefore, the upper intermediary element 52 drives the first storage body 41 again to rotate the first storage body 41 to the original position. In summary, the bubble water machine 3 can adjust the internal pressure to which the upper pressure bottle is subjected, and the user can easily clean all components of the upper pressure bottle. In addition, the inflatable bottle 56 of the sparkling water machine 3 is provided on the side of the pressure bottle 4, so the inflatable bottle 56 can store more gas (carbon dioxide). Although the present invention has been disclosed as above with preferred embodiments, it is not intended to limit the present invention. Anyone who has ordinary knowledge in the technical field can make some changes and modifications without departing from the spirit and scope of the present invention. Therefore, the protection scope of the present invention shall be deemed as defined by the appended patent application scope.

219: The first pressure relief component 2191: The first screw element 2192: first abutment element 2193: the first spring element 2181: The first receiving slot 3: Bubble water machine 4: Pressure bottle 40: top cover 401: Vent switch 402: top cover air plug 41: First containment body 41U: upper screw connection 41L: Lower screw connection 42: The first connection seat 420: first pressure relief zone 421: The first deflation channel 422: Top cover vent channel 43: The first airlock 431: The first pressure element 44: Valve element 441: The second vent channel 442: Valve screw connection 443: Stagnant water space 45: Second air plug 451: Second pressure element 46: Rotating pressure relief element 461: The third vent channel 47: Upper positioning element 48: Gas guide element 480U: U-shaped plate structure 480L: Long plate structure 481: Diversion channel 49: Lower positioning element 490: Water plug 491: The first intake passage 5: Inflatable mechanism 50: Second containment body 51: Second connection seat 51C: Cylindrical block 52: Upper intermediary component 52W: W type structure 521: Second intake passage 522: The first receiving slot 523: Push block 53: Intermediary components below 531: Third intake passage 532: Pressure relief component 5321: Second receiving slot 5321H: vent hole 5322H: through hole 5322: Screw connection element 5323: Abutment 5324: Spring element 54: L type linkage 55: Gas cylinder start switch 56: Inflatable bottle 56P: Jet pipeline 56N: Gas cylinder thimble 57: Enclosed shell below 571: Straight through hole 58: upper cover shell 581: Spring against block 582: Feedback spring element 8: liquid A-A: Section line B-B: Section line

FIG. 1 is a cross-sectional view of the first receiving slot 2181 and the first pressure relief component 219 of Taiwan Patent I618514. FIG. 2 is a perspective view of the sparkling water machine 3 of this embodiment. FIG. 3A illustrates a front view of the bubble water machine 3. FIG. 3B is an A-A cross-sectional view of the bubble water machine 3 in FIG. 3A, and FIG. 3C is an enlarged view of the portion X marked in FIG. 3B. FIG. 3C is an enlarged view of the portion X marked in FIG. 3B. FIG. 3D is a perspective view of the gas guiding element 48 at different angles. FIG. 3E is a cross-sectional view of the top cover 40. FIG. 3F is a perspective view of the first connecting base 42. FIG. 3G is a schematic diagram when the deflation switch 401 is turned on. FIG. 3H illustrates a perspective view of the first air blocking plug 43 embedded in the first pressure element 431 at different angles. FIG. 3I is a perspective view of the valve element 44 at different angles. FIG. 3J shows a perspective view of the second air blocking plug 45 embedded in the second pressure element 451 at different angles. FIG. 3K is a perspective view of the rotary pressure relief element 46 at different angles. FIG. 3L is a perspective view of different types of gas guide elements 48. FIG. 4A shows a left side view of the bubble water machine 3. FIG. 4B is a cross-sectional view taken along line B-B of the bubble water machine 3 in FIG. 4A. FIG. 4C is an enlarged view of the portion marked Y in FIG. 4B. 4D is a cross-sectional view showing the bottom of the first receiving body 41 alone. 4E is a cross-sectional view showing the lower positioning element 49 alone. 4F is a perspective view of the upper intermediary element 52 at different angles. 4G is a cross-sectional view showing the lower intermediary element 53 alone. FIG. 4H is a perspective view of the lower intermediary element 53 and the upper intermediary element 52. FIG. 5A shows a perspective view of the L-shaped link rod 54 abutting against the W-shaped structure 52W. FIG. 5B is a schematic perspective view of the upper intermediary element 52 driving the L-shaped linkage rod 54 to move downward. FIG. 5C is a schematic diagram of the L-shaped linkage rod 54 passing through the lower covering shell 57. FIG. 5D is a perspective view of the lower covering shell 57. FIG. 6A is a perspective view of the upper covering shell 58 at different angles. FIG. 6B is a schematic diagram of the assembly of the upper intermediary element 52 inside the upper cladding housing 58.

3: Bubble water machine

4: Pressure bottle

40: top cover

401: Vent switch

402: top cover air plug

41: First containment body

42: The first connection seat

421: The first deflation channel

422: Top cover vent channel

43: The first airlock

44: Valve element

441: The second vent channel

45: Second air plug

46: Rotating pressure relief element

47: Upper positioning element

49: Lower positioning element

490: Water plug

5: Inflatable mechanism

50: Second containment body

56: Inflatable bottle

8: liquid

Claims (10)

A bubble water machine, including: A pressure bottle, including: A first accommodating body, the bottom of the first accommodating body includes an upper end screw connection portion and a lower end screw connection portion; A first connecting seat screwed to the upper end of the first receiving body, the first connecting seat includes a first pressure relief area, and the first pressure relief area includes a first air release channel; A first air blocking plug, the bottom of the first air blocking plug covers the first air release channel; A first pressure applying element, the top end of the first air blocking plug is embedded in the first pressure applying element; A valve element screwed into the first pressure relief area, the valve element includes a second air release channel and a valve screw connection, and the valve element abuts against the first pressure element; A second air blocking plug, the bottom of the second air blocking plug covers the second vent channel; A second pressure applying element, the top end of the second air blocking plug is embedded in the second pressure applying element; A rotary pressure relief element is screwed to the valve screw connection portion, the rotary pressure relief element includes a third air release channel, and the rotary pressure relief element abuts against the second pressure applying element; An upper positioning element, which is screwed on the upper screw connection; A gas deflector element is arranged in the upper positioning element, and the bottom of the gas deflector element has a balanced pressure applying structure; A lower positioning element, which is screwed to the lower end screw connection portion, and the lower positioning element includes a first air intake channel; and A water plug, the balanced pressure structure abuts the top of the water plug, and the bottom of the water plug covers the first air intake channel; An inflation mechanism, including: A second connecting base, the lower end of the first receiving body is engaged with the second connecting base, and the second connecting base includes at least one cylindrical block; An upper intermediary element, the upper intermediary element includes a second air intake channel and at least one first accommodating groove, the second air intake channel communicates with the first air intake channel, and the cylindrical block is embedded in the first In a holding slot; A lower intermediary element connected to the upper intermediary element, the lower intermediary element including a third intake passage, the third intake passage communicating with the second intake passage; and An inflation bottle, the inflation bottle includes a jet line, and the jet line is embedded in the third air intake channel. The bubble water machine as described in item 1 of the patent application range, wherein the downward pressure of the valve element against the first pressure element is less than the downward pressure of the rotary pressure relief element against the second pressure element . The bubble water machine as described in item 1 of the patent application scope, wherein the pressure bottle further includes a top cover, the top cover includes a vent switch and a top cover plugging plug, and the venting switch abuts against the top cap to block air The top of the plug, and the first connecting seat further includes a top cover vent channel; when the vent switch is closed, the top cap plug plug covers the top cap vent channel; when the vent switch is turned on, the top The cover plug cannot cover the top cover vent channel. The bubble water machine as described in item 1 of the patent application scope, wherein the valve element further includes a stagnation space, and the stagnation space surrounds the second bleed passage. The bubble water machine as described in item 1 of the patent application scope, wherein the gas guide element further includes a plurality of guide channels, the guide channels are arranged in a radial pattern, and the lengths of the guide channels are different from each other . A pressure bottle, including: A first accommodating body, the bottom of the first accommodating body includes an upper end screw connection portion and a lower end screw connection portion; A first connecting seat screwed to the upper end of the first receiving body, the first connecting seat includes a first pressure relief area, and the first pressure relief area includes a first air release channel; A first air blocking plug, the bottom of the first air blocking plug covers the first air release channel; A first pressure applying element, the top end of the first air blocking plug is embedded in the first pressure applying element; A valve element screwed into the first pressure relief area, the valve element includes a second air release channel and a valve screw connection, and the valve element abuts against the first pressure element; A second air blocking plug, the bottom of the second air blocking plug covers the second vent channel; A second pressure applying element, the top end of the second air blocking plug is embedded in the second pressure applying element; A rotary pressure relief element is screwed to the valve screw connection portion, the rotary pressure relief element includes a third air release channel, and the rotary pressure relief element abuts against the second pressure applying element. The pressure bottle as described in item 6 of the patent application range, wherein the downward pressure of the valve element against the first pressure element is less than the downward pressure of the rotary pressure relief element against the second pressure element. The pressure bottle as described in item 6 of the patent application scope also includes: An upper positioning element, which is screwed on the upper screw connection; A gas deflector element is arranged in the upper positioning element, and the bottom of the gas deflector element has a balanced pressure applying structure; A lower positioning element, which is screwed to the lower end screw connection portion, and the lower positioning element includes a first air intake channel; and A water plug, the balanced pressure structure abuts the top of the water plug, and the bottom of the water plug covers the first air intake passage. The pressure bottle as described in item 6 of the patent application scope, wherein the valve element further includes a stagnation space, and the stagnation space surrounds the second bleed passage. The pressure bottle as described in item 6 of the patent application scope further includes a top cover, the top cover includes a bleed switch and a top cover air blocking plug, the bleed switch abuts the top of the top cover air blocking plug, and The first connection seat further includes a top cover vent channel; when the vent switch is closed, the top cap vent plug covers the top cap vent channel; when the vent switch is turned on, the top cap vent plug cannot Cover the top cover vent channel.

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