CN106745535B

CN106745535B - Motion induction type hydrogen-rich water cup

Info

Publication number: CN106745535B
Application number: CN201611265164.2A
Authority: CN
Inventors: 姜日忠; 朱全再
Original assignee: Fuzhou Pinxing Technology Development Co Ltd
Current assignee: Fuzhou Pinxing Technology Development Co Ltd
Priority date: 2016-12-30
Filing date: 2016-12-30
Publication date: 2020-12-08
Anticipated expiration: 2036-12-30
Also published as: CN106745535A

Abstract

The invention relates to an action induction type hydrogen-rich water cup which comprises a cup body, a cup cover and a cup base, wherein the cup body, the cup cover and the cup base are vertically communicated; the cup cover is detachably connected with the top of the cup body in a sealing way; the cup seat is detachably and hermetically connected with the bottom of the cup body; a filter element component capable of generating electrolyte is arranged on the inner side of the cup cover; the top of the cup base is provided with an electrolytic electrode which can extend into the cup body, and a rechargeable battery is arranged in the cup base; a first time delay switch controls the on-off of the electrolysis electrode; the cup body is formed by sleeving an inner container and an outer container; the inner container and the outer container are enclosed to form a cavity; an action trigger device is arranged in the cavity; the action trigger device comprises an induction cavity arranged along the axial direction of the cup body; a first guide plate group 'and a second guide plate group' which are composed of two guide plates arranged at intervals are symmetrically arranged at two ends of the induction cavity respectively; one of the first and second conductive sheets is electrically connected to each other, and the other conductive sheet is connected to two ends of the trigger circuit formed by the first delay switch and the rechargeable battery.

Description

Motion induction type hydrogen-rich water cup

Technical Field

The invention relates to a water cup, in particular to a motion induction type hydrogen-rich water cup.

Background

With the development of the technology and the application of new materials and new technologies, the hydrogen-rich effect of the hydrogen-rich cup commonly used in daily life is obviously improved, and great health guarantee and convenience are provided for the life of people.

Chinese patent document with application number CN 201520919118.4 discloses a hydrogen-rich cup structure, which comprises a base cover, wherein the base cover is connected with a base through threads, a switch button is arranged on the base, the switch button is connected with a power supply through a connecting circuit, a plate electrode is connected with the plate electrode through a plate electrode screw in the base, the lower part of the plate electrode is the power supply, an electrolytic circuit part is arranged below the power supply, a charging port for charging is arranged on the base, the upper part of the base is connected with a cup body, the upper part of the cup body is connected with a middle cover, the upper part of the middle cover is connected with the upper cover. This hydrogen-rich cup structure adopts the switch button, and the switch button sets up on the base, and often can take place the button dead, the button is bad phenomenon such as soft partially, leads to the button to be inoperative, and in inconvenient visual occasion, for example in dark night, only rely on the accurate position that the button was hardly found in the touch moreover, in addition, adopts the switch button to be unfavorable for wasing the drinking cup, produces the short circuit or the electric leakage problem because of intaking easily, uses insecurely, and the life-span is low.

Disclosure of Invention

In order to solve the technical problems, the invention provides the motion induction type hydrogen-enriched water cup which is convenient to use, prolongs the service life, improves the safety, can realize the opening of the electrolysis device through specific motions without needing to open the electrolysis by a key, increases the use pleasure, and can avoid vibration, swing and other non-opening motions to trigger the opening of the electrolysis device.

The technical scheme of the invention is as follows:

a motion induction type hydrogen-enriched water cup comprises a cup body, a cup cover and a cup base which are communicated up and down; the cup cover is detachably connected with the top of the cup body in a sealing way; the cup seat is detachably and hermetically connected with the bottom of the cup body; a filter element component capable of generating electrolyte is arranged on the inner side of the cup cover; the top of the cup base is provided with an electrolytic electrode which can extend into the cup body, and a rechargeable battery is arranged in the cup base; a first time delay switch controls the on-off of the electrolysis electrode; the cup body is formed by sleeving an inner container and an outer container; the inner container and the outer container are enclosed to form a cavity; an action trigger device is arranged in the cavity; the action trigger device comprises an induction cavity arranged along the axial direction of the cup body; a first guide plate group 'and a second guide plate group' which are composed of two guide plates arranged at intervals are symmetrically arranged at two ends of the induction cavity respectively; one of the first and second conducting plate sets is electrically connected, the other conducting plate is connected to two ends of the trigger circuit composed of the first delay switch and the rechargeable battery, the trigger circuit forms a loop to trigger the first delay switch to close; the first time delay switch is connected with the anode and the cathode of the rechargeable battery after being connected with the electrolysis electrode in series to form an electrolysis circuit; the induction cavity is filled with conductive liquid; the volume of the conductive liquid is less than the volume of the sensing chamber.

The cup body is provided with a cup body, wherein the cup body is provided with a plurality of groups of action triggering devices, and the action triggering devices in the two groups are arranged on the other side of the cup body opposite to the action triggering devices in the first group.

Wherein, the side wall of the cup body where at least one of the first group of action trigger devices and the second group of action trigger devices is arranged is also provided with an arc-shaped handle; a flow channel is arranged in the handle; two ends of the flow passage are respectively communicated with the induction cavity; the second group of action trigger devices trigger the second delay switch to be closed; the second delay switch is connected in series with a resistor and then connected in parallel with the electrolytic circuit.

Wherein the volume of the conductive liquid in the second set of motion-trigger devices is less than the volume of the conductive liquid in the first set of motion-trigger devices.

Wherein, the top of the cup base is also provided with an electrolyte sensor which can determine whether the electrolyte exists or not; a trigger switch is connected in series in the electrolysis circuit; the electrolyte sensor triggers the trigger switch to open and close.

Wherein the filter element member is provided with a plurality of through holes.

Wherein the filter element member is formed by overlapping a plurality of sheet material layers; the sectional area of the sheet material layer is changed in a gradient and gradual manner; the outer edge of the sheet material layer is arranged in a zigzag shape; the plurality of sheet-like material layers at least comprise a medical stone layer, a calcium ion layer, a magnesium ion layer, a zinc ion layer, an iron ion layer and a selenium ion layer.

Wherein the filter element component is a honeycomb complex formed by compounding a plurality of spherical particles; the plurality of honeycomb-shaped complexes at least comprise medical stone spherical particles, calcium ion spherical particles, magnesium ion spherical particles, zinc ion spherical particles, iron ion spherical particles and selenium ion spherical particles.

A use method of the motion induction type hydrogen-rich water cup comprises the following use steps:

firstly, inverting a hydrogen-rich water cup, and contacting water in the cup body with a filter element component to filter out electrolyte dissolved in the water;

holding the middle part of the cup body to horizontally rotate left and right to trigger the first delay switch to start;

controlling the electrolysis electrode to start electrolysis by the first time delay switch, and automatically stopping electrolysis after electrolysis for a period of time.

secondly, the hydrogen-enriched water cup is horizontally rotated back and forth left and right by pinching the handle downwards, and at the moment, the first group of action trigger devices firstly trigger the first delay switch to start;

controlling the electrolysis electrode to start electrolysis by the first delay switch;

increasing the rotation speed to enable the second group of action trigger devices to trigger the second delay switch to be closed, forming a loop with a circuit connected in parallel with the electrolytic circuit, reducing the resistance of the electrolytic circuit, increasing the current and increasing the power;

after electrolyzing for a period of time, automatically stopping electrolyzing.

The invention has the following beneficial effects:

1. the invention not only does not need to press a key to start electrolysis, has convenient use, prolongs the service life and improves the safety, but also can realize the starting of the electrolysis device through specific actions, increases the use pleasure and simultaneously can avoid vibration, swing and other non-starting actions to trigger the electrolysis device to start.

2. The second group of action trigger device and the handle can increase the electrolysis power and improve the electrolysis speed when needed by the action amplitude.

3. The invention increases the contact area of the filter device and the water flow through the through holes and the zigzag structure of the filter device, thereby rapidly obtaining the electrolyte.

4. The invention can dissolve nearly 20 electrolyte materials such as potassium, sodium, calcium, magnesium, silicon, manganese, titanium, phosphorus and the like which are necessary for human bodies through electrolyte raw materials similar to medical stones, and can enhance the immunologic function of the human bodies and improve the anti-infection capability of the human bodies after long-term drinking. Meanwhile, the medical stone has strong adsorption rate to elements such as cadmium, lead and the like which are harmful to human bodies and bacteria, and the adsorption rate to escherichia coli is over 95 percent.

Drawings

Fig. 1 is a schematic overall structure diagram of a first embodiment of the present invention;

FIG. 2 is a schematic diagram of an inverted hydrogen-rich cup of dissolved electrolyte in accordance with an embodiment of the present invention;

FIG. 3 is a schematic diagram of an embodiment of a hydrogen-rich cup triggered to electrolyze by an action;

FIG. 4 is a schematic view of a filter element of the motion-sensitive hydrogen-rich water cup of the present invention being a sheet-like material layer;

FIG. 5 is a schematic view of a honeycomb-shaped filter element component of the motion-sensing hydrogen-rich water cup according to the present invention;

FIG. 6 is a schematic diagram of a trigger circuit of a hydrogen-rich water cup according to an embodiment of the invention;

FIG. 7 is a schematic diagram of an electrolytic circuit of a hydrogen-rich water cup according to an embodiment of the invention;

FIG. 8 is a schematic overall structure diagram of a second embodiment of the present invention;

FIG. 9 is a schematic diagram of a second hydrogen-rich cup triggered to electrolyze by an action according to an embodiment of the present invention;

FIG. 10 is a schematic diagram of a hydrogen-rich cup activated by an action to trigger power-up electrolysis according to an embodiment of the present invention;

FIG. 11 is a schematic diagram of a trigger circuit for hydrogen-rich water cup plus power electrolysis in accordance with an embodiment of the present invention;

FIG. 12 is a schematic diagram of an electrolytic circuit of a hydrogen-rich water cup according to an embodiment of the invention.

The reference numbers in the figures denote:

1-cup body, 11-inner container, 12-outer container, 13-cavity, 15-induction cavity, 16-guide sheet, 16 '-first guide sheet group, 16' -second guide sheet group, 17-conductive liquid, 2-cup cover, 21-filter element member, 211-sheet material layer, 212-through hole, 213-honeycomb complex, 3-cup seat, 31-electrolytic electrode, 32-rechargeable battery, 33-electrolyte sensor, 4-first delay switch, 5-handle, 51-runner, 6-trigger switch, 7-second delay switch and 8-resistor.

Detailed Description

The invention is described in detail below with reference to the figures and the specific embodiments.

The first embodiment is as follows: as shown in fig. 1, the motion induction type hydrogen-enriched water cup comprises a cup body 1, a cup cover 2 and a cup base 3 which are vertically communicated; the cup cover 2 is detachably and hermetically connected with the top of the cup body 1, and in the embodiment, the connection adopts threaded connection; the cup base 3 is detachably and hermetically connected with the bottom of the cup body 1, and in the embodiment, the connection is also in threaded connection; the cup body 1, the cup cover 2 and the cup base 3 are combined into a complete cup for use; a filter element component 21 capable of generating electrolyte is arranged on the inner side of the cup cover 2; as shown in fig. 4 and 5, in this embodiment, the filter element member 21 may be formed by overlapping a plurality of sheet material layers 211 or by combining a plurality of spherical particles to form a honeycomb complex 213.

When the sheet material layer 211 is used, as shown in fig. 4, the cross-sectional area of the sheet material layer 211 is gradually changed in a gradient manner, and the gradient gradually narrows from top to bottom; the outer edge of the sheet material layer 211 is arranged in a zigzag shape to increase the contact area with water and improve the dissolving speed; the plurality of sheet-shaped material layers 211 at least comprise a medical stone layer, a calcium ion layer, a magnesium ion layer, a zinc ion layer, an iron ion layer and a selenium ion layer, and the immunity of the human body can be enhanced and the anti-infection capability of the human body can be improved after long-term drinking. Meanwhile, the medical stone has strong adsorption rate to elements such as cadmium, lead and the like which are harmful to human bodies and bacteria, and the adsorption rate to escherichia coli is over 95 percent.

As shown in fig. 5, when the honeycomb-shaped complex 213 is used, the plurality of honeycomb-shaped complexes 213 include at least medical stone spherical particles, calcium ion spherical particles, magnesium ion spherical particles, zinc ion spherical particles, iron ion spherical particles, and selenium ion spherical particles.

Further, as shown in fig. 1, an electrolysis electrode 31 capable of extending into the cup body 1 is arranged at the top of the cup base 3, and a rechargeable battery 32 is arranged inside the cup base 3; the rechargeable battery 32 is hermetically arranged in the cup base 3, prevents water from entering and is provided with a charging port externally connected with a charging wire; a first time delay switch 4 controls the on-off of the electrolysis electrode 31, and when the first time delay switch is electrified, the first time delay switch is kept closed for a certain time, so that the electrolysis electrode 31 is continuously electrolyzed for a certain time.

The cup body 1 is formed by sleeving an inner container 11 and an outer container 12; the inner container 11 and the outer container 12 enclose to form a cavity 13; an action trigger device is arranged in the cavity 13; the action trigger device comprises an induction cavity 15 arranged along the axial direction of the cup body 1, and in the embodiment, the induction cavity 15 is a liquid pipe with two expanded ends; a first guide plate set 16' and a second guide plate set 16 ″ which are composed of two guide plates 16 arranged at intervals are respectively and symmetrically arranged at two ends of the induction cavity 15; as shown in fig. 6, one of the first and second blade sets 16', 16 ″ is electrically connected to each other, and the other blade 16 is connected to two ends of the trigger circuit formed by the first delay switch 4 and the rechargeable battery 32, respectively, and the trigger circuit forms a loop to trigger the first delay switch 4 to close; as shown in fig. 7, the first delay switch 4 is connected in series with the electrolysis electrode 31 and then connected to the positive and negative electrodes of the rechargeable battery 32 to form an electrolysis circuit; the sensing cavity 15 is filled with conductive liquid 17; the volume of conducting liquid 17 is less than the volume of induction cavity 15, therefore, as shown in fig. 3, the circuit is only communicated and triggers first time delay switch 4 to close when conducting liquid 17 submerges four guide vanes 16 simultaneously, and the situation only occurs when the middle part of cup body 1 is held horizontally to rotate back and forth, and the situation can be realized through the action of centrifugal force, no matter vibration, shaking, swinging and other actions can not occur, so that the carrying and walking are avoided, and the situation of self-electrolysis in the situations of vibration and the like on a vehicle is prevented.

Further, as shown in fig. 1 and 6, an electrolyte sensor 33 for determining the presence or absence of electrolyte is further disposed on the top of the cup holder 3; a trigger switch 6 is connected in series in the electrolysis circuit; the electrolyte sensor 33 triggers the trigger switch 6 to be switched on and off; when there is no water or electrolyte in the cup, the electrolyte sensor 33 triggers the trigger switch 6 to turn off, so that the electrolysis electrode 31 does not work.

Further, as shown in fig. 4 and 5, the filter element member 21 is provided with a plurality of through holes 212 to facilitate the water to enter and exit the filter element member 21.

A use method of a motion induction type hydrogen-rich water cup comprises the following use steps:

firstly, as shown in fig. 2, the hydrogen-rich water cup is inverted, water in the cup body 1 contacts with the filter element component 21, and electrolyte is filtered out and dissolved in the water;

secondly, as shown in fig. 3, the middle part of the cup body 1 is held to horizontally rotate left and right back and forth, the conductive liquid 17 flows to the two sides of the induction cavity 15 under the action of centrifugal force and submerges four guide vanes 16, and the first delay switch 4 is triggered to start;

controlling the electrolysis electrode 31 to start electrolysis by the first delay switch 4, and automatically stopping electrolysis after electrolysis for a period of time;

fourthly, the cup cover 2 is opened for drinking.

Example two:

as shown in fig. 8, the difference between the second embodiment and the first embodiment is: the cup body 1 is provided with two groups of action triggering devices, and the side wall of at least one of the cup body 1 where the first group of action triggering devices and the second group of action triggering devices are arranged is also provided with an arc-shaped handle 5; a flow passage 51 is arranged in the handle 5; two ends of the flow passage 51 are respectively communicated with the induction cavity 15; the volume of the conductive liquid 17 in the second set of motion-trigger means is smaller than the volume of the conductive liquid 17 in the first set of motion-trigger means; taking the example of providing a handle 5, as shown in fig. 11, the second group of motion-triggering devices triggers the second delay switch 7 to close; as shown in FIG. 12, the second delay switch 7 is connected in series with a resistor 8 and then connected in parallel with the electrolysis circuit, so that the electrolysis power can be increased by action when in need, and rapid electrolysis can be realized.

firstly, inverting the hydrogen-rich water cup, and contacting the water in the cup body 1 with the filter element member 21 to filter out electrolyte dissolved in the water;

secondly, as shown in fig. 9, the handle 5 is pinched downwards by the handle 5 to horizontally rotate the hydrogen-enriched water cup back and forth left and right, at this time, the second group of action trigger devices are arranged below the first group of action trigger devices, the conductive liquid 17 of the second group of action trigger devices is accumulated in the flow channel 51 under the action of gravity, and the first group of action trigger devices firstly trigger the first delay switch 4 to start;

controlling the electrolysis electrode 31 to start electrolysis by the first delay switch 4;

as shown in fig. 10, the rotation speed is increased, the conductive liquid 17 accumulated in the flow channel 51 flows out of the flow channel 51 from both sides under the action of a larger centrifugal force, and the four guide vanes 16 on both sides of the sensing cavity 15 are immersed, so that the second group of action trigger devices trigger the second delay switch 7 to be closed, the second delay switch 7 enables a circuit connected in parallel with the electrolytic circuit to form a loop, the resistance of the electrolytic circuit is reduced, the current is increased, and the power is increased;

after the electrolysis is carried out for a period of time, the first delay switch 4 and the second delay switch 7 are sequentially and automatically switched off, so that the electrolysis is automatically stopped;

sixthly, the cup cover 2 is opened for drinking.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a hydrogen-rich drinking cup of action induction type which characterized in that: comprises a cup body (1), a cup cover (2) and a cup seat (3) which are vertically communicated; the cup cover (2) is detachably connected with the top of the cup body (1) in a sealing way; the cup seat (3) is detachably and hermetically connected with the bottom of the cup body (1); a filter element component (21) capable of generating electrolyte is arranged on the inner side of the cup cover (2); an electrolytic electrode (31) capable of extending into the cup body (1) is arranged at the top of the cup seat (3), and a rechargeable battery (32) is arranged in the cup seat (3); a first time delay switch (4) controls the electrolysis electrode (31) to be switched on and off; the cup body (1) is formed by sleeving an inner container (11) and an outer container (12); the inner container (11) and the outer container (12) enclose to form a cavity (13); an action trigger device is arranged in the cavity (13); the action trigger device comprises an induction cavity (15) which is arranged along the axial direction of the cup body (1); a first guide plate group (16 ') and a second guide plate group (16') which are composed of two guide plates (16) arranged at intervals are symmetrically arranged at two ends of the induction cavity (15) respectively; one of the guide blades (16) of the first guide blade group (16 ') and the second guide blade group (16'), is electrically connected with each other, the other guide blade (16) is respectively connected with two ends of a trigger circuit consisting of the first delay switch (4) and the rechargeable battery (32), and the trigger circuit forms a loop to trigger the first delay switch (4) to be closed; the first time delay switch (4) is additionally connected with the positive and negative electrodes of the rechargeable battery (32) in series after being connected with the electrolysis electrode (31) to form an electrolysis circuit; the induction cavity (15) is filled with conductive liquid (17); the volume of the conductive liquid (17) is smaller than the volume of the sensing chamber (15).

2. The motion-sensing hydrogen-rich water cup as claimed in claim 1, wherein: the action trigger devices are arranged in two groups, and the second group of action trigger devices is arranged on the other side of the cup body (1) opposite to the first group of action trigger devices.

3. The motion-sensitive hydrogen-rich water cup as claimed in claim 2, wherein: an arc-shaped handle (5) is also arranged on the side wall of the cup body (1) where at least one of the first group of action trigger device and the second group of action trigger device is positioned; a flow channel (51) is arranged in the handle (5); two ends of the flow passage (51) are respectively communicated with the induction cavity (15); the second group of action trigger devices trigger the second delay switch (7) to be closed; the second delay switch (7) is connected in series with a resistor (8) and then is connected in parallel with the electrolytic circuit.

4. The motion-sensitive hydrogen-rich water cup as claimed in claim 3, wherein: the volume of the conductive liquid (17) in the second set of motion-trigger means is smaller than the volume of the conductive liquid (17) in the first set of motion-trigger means.

5. The motion-sensing hydrogen-rich water cup as claimed in claim 1, wherein: the top of the cup seat (3) is also provided with an electrolyte sensor (33) which can determine whether the electrolyte exists or not; a trigger switch (6) is connected in series in the electrolysis circuit; the electrolyte sensor (33) triggers the trigger switch (6) to open and close.

6. The motion-sensitive hydrogen-rich water cup as claimed in claim 5, wherein: the filter element member (21) is provided with a plurality of through holes (212).

7. The motion-sensitive hydrogen-rich water cup as claimed in claim 6, wherein: the filter element member (21) is formed by overlapping a plurality of sheet material layers (211); the sectional area of the sheet material layer (211) is changed in a gradient and gradual manner; the outer edge of the sheet material layer (211) is arranged in a zigzag shape; the plurality of sheet material layers (211) at least comprise a medical stone layer, a calcium ion layer, a magnesium ion layer, a zinc ion layer, an iron ion layer and a selenium ion layer.

8. The motion-sensitive hydrogen-rich water cup as claimed in claim 5, wherein: the filter element member (21) is a honeycomb composite body (213) formed by compounding a plurality of spherical particles; the plurality of honeycomb-shaped complexes (213) at least include medical stone spherical particles, calcium ion spherical particles, magnesium ion spherical particles, zinc ion spherical particles, iron ion spherical particles and selenium ion spherical particles.