CN211005640U - Hydrogen production equipment - Google Patents

Abstract

The utility model relates to a hydrogen production equipment, which comprises a hydrogen supply device and an anion generating device. The negative ion generating device comprises an ionization cavity, a discharge electrode and a negative ion emitter, wherein the discharge electrode and the negative ion emitter are arranged in the ionization cavity, the ionization cavity is provided with an air inlet and an air outlet, the hydrogen supply device is communicated with the air inlet of the ionization cavity to introduce hydrogen into the ionization cavity, the discharge electrode is used for releasing high-speed electrons into the ionization cavity, and the negative ion emitter is used for emitting the hydrogen in the ionization cavity out of the ionization cavity through the air outlet. The hydrogen supply device produces high-purity hydrogen, and the hydrogen is introduced into the negative ion generating device to ionize the hydrogen at high pressure to generate hydrogen with negative potential, so that the negative ions required by the electrical activity of organism tissues can be supplemented, and the treatment and health care effects are improved.

Description

Hydrogen production equipment

Technical Field

The utility model relates to a hydrogen manufacturing field especially relates to a hydrogen production equipment.

Background

The household hydrogen absorption machine can release hydrogen, is auxiliary medical health-care equipment, can be used for auxiliary treatment of hypertension, diabetes, lung diseases, blood diseases and the like, has a good treatment effect, and also has a health-care function and prevents the generation of diseases. The mainstream view about the pathophysiological mechanism of hydrogen treatment is the selective oxidation resistance of hydrogen, and on the basis of the selective oxidation resistance, the hydrogen is proved to have a treatment effect on oxidative damage, inflammatory reaction, apoptosis, abnormal vascular proliferation and the like in various disease processes in sequence. At present, most of domestic hydrogen absorbers only provide hydrogen, and the treatment and health care effects of the domestic hydrogen absorbers are to be further enhanced.

SUMMERY OF THE UTILITY MODEL

Based on this, there is a need for a hydrogen generation device to improve the therapeutic and health-care effects of the conventional hydrogen absorption machine.

The hydrogen production equipment is characterized by comprising a hydrogen supply device and a negative ion generating device;

the negative ion generating device comprises an ionization cavity, a discharge electrode and a negative ion emitter, wherein the discharge electrode and the negative ion emitter are arranged in the ionization cavity, the ionization cavity is provided with an air inlet and an air outlet, the hydrogen supply device is communicated with the air inlet of the ionization cavity so as to introduce hydrogen into the ionization cavity, the discharge electrode is used for releasing high-speed electrons into the ionization cavity, and the negative ion emitter is used for transmitting the hydrogen in the ionization cavity out of the air outlet.

In one embodiment, the hydrogen production equipment further comprises a hydrogen concentration detection mechanism, and the hydrogen concentration detection mechanism is arranged on a pipeline connecting the hydrogen supply device and the ionization chamber.

In one embodiment, the hydrogen concentration detection mechanism is disposed near an air inlet of the ionization chamber.

In one embodiment, the hydrogen production equipment further comprises a control device, the control device is electrically connected with the hydrogen concentration detection mechanism and the negative ion generation device, and when the hydrogen concentration detection mechanism detects that the hydrogen concentration is not less than a set value, the control device controls the negative ion generation device to be started.

In one embodiment, the control device further adjusts the working power of the negative ion generating device according to the hydrogen concentration detected by the hydrogen concentration detecting mechanism.

In one embodiment, the hydrogen production equipment further comprises a gas-water separation device, the gas-water separation device is arranged on a pipeline of the hydrogen supply device communicated with the ionization chamber, and the gas-water separation device is used for separating hydrogen and moisture.

In one embodiment, the hydrogen supply device comprises a water electrolysis chamber and a water storage container, the water storage container is communicated with the water electrolysis chamber to provide water for the water electrolysis chamber, and the water electrolysis chamber is provided with a hydrogen outlet which is communicated with the air inlet of the ionization chamber.

In one embodiment, the hydrogen-producing apparatus further comprises at least one of the following detectors:

the liquid level detector is used for detecting the height of the liquid level of the water storage container;

the TDS detector is used for detecting the water quality condition in the water storage container;

the inclination detector is used for detecting the inclination condition of the water storage container;

the flow velocity detector is used for detecting the flow velocity of liquid in a liquid pipeline of the water storage container leading to the water electrolysis chamber;

a temperature detector for detecting a temperature within the water electrolysis chamber; and

and a power supply voltage detector for detecting the power supply voltage.

In one embodiment, the hydrogen production equipment further comprises an alarm which is electrically connected with at least one detector, and when the detection result of any one of the detectors electrically connected with the alarm exceeds a set range, the alarm gives an alarm.

In one embodiment, the hydrogen gas supply device and the negative ion generating device are contained in the same housing.

Compared with the prior art, the hydrogen production equipment has the following beneficial effects:

the hydrogen production equipment is provided with the hydrogen supply device and the negative ion generating device, the hydrogen supply device produces high-purity hydrogen, and the hydrogen is introduced into the negative ion generating device to ionize the hydrogen at high pressure to generate hydrogen with negative potential, so that negative ions required by the electrical activity of organism tissues can be supplemented, and the treatment and health care effects are improved.

Drawings

FIG. 1 is a schematic structural diagram of a hydrogen production apparatus according to an embodiment;

FIG. 2 is a schematic view of hydrogen gas passing through a negative ion generating device in the hydrogen production apparatus shown in FIG. 1;

FIG. 3 is a schematic circuit control diagram of the hydrogen generation apparatus shown in FIG. 1.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1 and fig. 2, a hydrogen generation apparatus 100 according to an embodiment of the present invention includes a hydrogen gas supply device and an anion generator.

The negative ion generating device includes an ionization chamber 112, and a discharge electrode 114 and a negative ion emitter 116 disposed within the ionization chamber 112. The ionization chamber 112 is provided with an air inlet and an air outlet 118, and the hydrogen supply device is communicated with the air inlet of the ionization chamber 112 to introduce hydrogen into the ionization chamber 112. The discharge electrode 114 is used to discharge high-speed electrons into the ionization chamber 112. The negative ion emitter 116 is used to emit the hydrogen gas in the ionization chamber 112 out the gas outlet 118.

The negative ion generating device is characterized in that input direct current or alternating current is processed by an EMI processing circuit and a lightning stroke protection circuit, and then is increased to alternating current high voltage through a pulse type circuit, an overvoltage current-limiting circuit, a high-low voltage isolation circuit and the like, then pure direct current negative high voltage is obtained after rectification and filtration through special grade electronic materials, the direct current negative high voltage is connected to a release tip made of metal or carbon elements, high corona is generated by the direct current high voltage at the tip, a large amount of electrons are emitted at high speed, and the electrons cannot exist in the air for a long time (the service life is only ns grade), and can be captured by hydrogen molecules, so that negative ions are generated.

The negative ion generator adopts the principle of single polarity, negative high voltage and point discharge to ionize partial hydrogen molecules in the ionization chamber 112 at high voltage to generate hydrogen ions with negative charges, the negative ion emitter 116 emits the hydrogen containing negative hydrogen ions out of the ionization chamber 112, and the concentration of the hydrogen negative ions at a position 30 cm away from the negative ion emitter 116 is about 7 × 10⁷Per cm²The concentration of the negative hydrogen ions at a distance of 4 to 5 m from the negative ion emitter 116 is about 3 to 4 ten thousand/cm 2. The negative hydrogen ions form a gas flow under the driving of the negative charges and enter the nostrils through the hydrogen absorption tube, so as to enter the body of the user.

Negative potential hydrogen is littleer than negative oxygen ion volume, and human blood brain barrier is changeed to the less granule footpath anion of being changeed and is changeed and see through human blood brain barrier, and the positive charge of neutralizing human metabolism production in addition strong reducibility and the penetrability that hydrogen itself has have stronger treatment and health care effect to the health.

Firstly, in a living body, each cell is like a micro battery, and the potential difference between the inside and the outside of a cell membrane is 50-90 millivolts. It is the continuous charging and discharging function of these "batteries" that the nervous system of the body can transmit the visual, auditory and other signals to the brain, or transmit the instructions of the brain to various organs of the body. The electrical activity of body tissues needs to be maintained by the constant replenishment of negative ions. Once the organism is not supplemented with negative ions, normal physiological activities can be affected, and chest distress, dizziness and even diseases can be caused.

Secondly, since viruses attacking human cells generally have negative charges, if human cells also have negative charges, the viruses lose their ability to attack living cells due to the action of homopolar repulsion.

Finally, the negative ions can enter the lung through respiration, and generate a neutralizing physiological health-care effect on the human body through direct stimulation of various tissues of the human body and interaction of nerve reflection and body fluid.

As shown in fig. 1, in one example, hydrogen production apparatus 100 further includes hydrogen concentration detection mechanism 130, and hydrogen concentration detection mechanism 130 is provided on a pipe that communicates the hydrogen gas supply device and ionization chamber 112, and more specifically, hydrogen concentration detection mechanism 130 is provided near an inlet of ionization chamber 112. The hydrogen concentration detection mechanism 130 and the negative ion generating device are electrically connected to the control device respectively. When the hydrogen concentration detection mechanism 130 detects that the hydrogen concentration is not less than the hydrogen concentration set value, the control device controls the negative ion generating device to be started.

Further, the negative ion generating device controls the intensity of the negative ion ionization according to the level of the hydrogen concentration detected by the hydrogen concentration detecting mechanism 130.

In the specific example shown in fig. 1, the hydrogen gas supply device comprises a water electrolysis chamber 124 and a water storage tank 122, the water storage tank 122 is communicated with the water electrolysis chamber 124 to provide water source for the water electrolysis chamber 124, the water electrolysis chamber 124 is provided with a hydrogen outlet 1242, and the hydrogen outlet 1242 is communicated with the air inlet of the ionization chamber 112.

The water filling port 1222 of the water storage container 122 is leaked to the outside of the upper part of the whole machine, and pure water is filled into the container from the water filling port 1222 when the water storage container is used. The water storage container 122 is further provided with a drain port for discharging water stored for a long time or water with a TDS defect. The water storage tank 122 is provided above the water electrolysis chamber 124 and supplies pure water to the water electrolysis chamber 124 by gravity, or the water storage tank 122 may supply pure water to the water electrolysis chamber 124 by the water pump 160. The water electrolysis chamber 124 has a water inlet 1246, an oxygen outlet 1244 and a hydrogen outlet 1242, and oxygen is discharged to the outside of the machine through a pipe.

The hydrogen production apparatus 100 of the above example uses pure water as a raw material, and does not require other raw materials, and only needs to periodically add or replace pure water. Oxygen generated after electrolysis is discharged out of the machine body, so that the environment is not polluted, and the method is green and environment-friendly.

The hydrogen production equipment 100 is provided with a control device (not shown) to control the operation of each component of the whole machine, and a monitoring system electrically connected with the control device, including various detectors and alarms (not shown), to monitor the operation state of the machine, so as to realize the intelligent control of the whole machine. When the detection result of the detector exceeds the set range, the control device controls the alarm to give an alarm, and can also control the corresponding part or the whole machine to stop, so that adverse effects are avoided.

The water storage container 122 is provided with a liquid level detector 141 electrically connected to the alarm, and the liquid level detector 141 detects the level of the liquid in the water storage container 122. When the liquid level detector 141 detects that the liquid level of the water storage container 122 is not higher than the set range, the alarm gives out a water shortage alarm to remind a user of adding water in time.

The water container 122 is further provided with a TDS detector 142 electrically connected to the alarm for detecting water quality. When the detection result of the TDS detector 142 exceeds the set range, the alarm gives an alarm that the water quality is not qualified.

The water storage container 122 is further provided with an inclination detector 143 electrically connected with the alarm, and when the water storage container 122 is excessively inclined, the alarm gives a water tank inclination alarm to remind the user of the overflow condition of the liquid.

The pipe of the water storage container 122 leading to the water electrolysis chamber 124 is provided with a flow rate detector 144 to detect the flow rate of water, and when the flow rate does not meet the requirement, the electrolysis is stopped and an alarm is given.

A temperature detector 145 is provided in the water electrolysis chamber 124 to detect the temperature inside the water electrolysis chamber 124. When the temperature detected by the temperature detector 145 exceeds a set value, the alarm gives an over-temperature alarm, and the machine stops working to prevent the over-temperature.

The power supply can be 220V commercial power or low-voltage battery power supply. The hydrogen production device 100 is powered by a battery, and may further be provided with a power supply voltage detector (not shown), which detects the voltage of the battery through a sampling circuit, and prompts charging when the detected voltage is too low.

The result detected by the monitoring system is transmitted to the control device through a digital signal, and the control device sends commands to the power supply voltage transformation circuit, the hydrogen power supply circuit and the negative high-voltage circuit to realize the functions.

As shown in fig. 1, in one example, the hydrogen production apparatus 100 further includes a gas-water separation device 150, the gas-water separation device 150 is disposed on a pipe where the hydrogen supply device communicates with the ionization chamber 112, and the gas-water separation device 150 is used for separating hydrogen and moisture.

In one example, the gas-water separation device 150 includes a separation chamber and a waterproof, gas-permeable membrane and a water vapor filter element disposed within the separation chamber. The separation chamber is provided with a separation inlet used for being communicated with the hydrogen supply device and a separation outlet used for being communicated with the ionization chamber 112, the waterproof breathable membrane is arranged at one side close to the separation inlet, and the water vapor filter element is arranged at one side close to the separation outlet.

Here, the gas-water separation device 150 is first provided with a waterproof and breathable membrane which is not ventilated with water to prevent liquid water from passing through, and then is provided with a water vapor filter element which can remove water vapor, so that liquid water and gaseous water in the hydrogen product of the hydrogen supply device are isolated, only hydrogen gas passes through, and water is prevented from entering the anion generation device.

As shown in figure 3, the whole machine is controlled by a microcomputer control circuit, a power supply voltage transformation circuit converts the voltage of an external power supply or a battery power supply into a low voltage (2V-60V) required by a hydrogen supply device and a high voltage (10KV-200KV) required by a negative ion generating device, the hydrogen supply circuit provides energy for the hydrogen supply device to control the concentration, the speed and the start and stop of hydrogen production, and the negative high voltage circuit provides energy for the negative ion generating device to control the ionization intensity, the speed and the start and stop of negative ions.

The microcomputer control circuit consists of a computer chip control part and a man-machine panel interaction part, wherein the man-machine panel interaction part controls the operation of the machine by keys or touch liquid crystal and the like outside the machine body; the computer chip control part integrally and intelligently controls the work and the cooperation of each part of the power supply voltage transformation circuit, the hydrogen power supply circuit and the negative high-voltage circuit.

The hydrogen production equipment 100 can be made into a portable type or a table type, the portable type can be a lug type, a portable type or other portable types, the table type can be a split type, and the table type can also be an integrated machine, and the whole machine is contained in the same casing. The hanger type negative ion emitting device does not need a hydrogen absorption tube, and the air outlet of the negative ion emitting device can be directly placed near the nostril. Other machines require a hydrogen tube, one end of which is connected to the air outlet of the negative ion emitting part of the machine body and the other end is a nose tube part, and the nose tube part of the hydrogen tube is inserted into the nostril.

The hydrogen production equipment is provided with a hydrogen supply device and an anion generating device, wherein the hydrogen supply device produces high-purity hydrogen (more than 99.99 percent), and the hydrogen is introduced into the anion generating device to ionize the hydrogen at high pressure to generate hydrogen with negative potential, so that the negative ions required by the electrical activity of organism tissues can be supplemented, and the medical care effect is improved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The hydrogen production equipment is characterized by comprising a hydrogen supply device and a negative ion generating device;

the negative ion generating device comprises an ionization cavity, a discharge electrode and a negative ion emitter, wherein the discharge electrode and the negative ion emitter are arranged in the ionization cavity, the ionization cavity is provided with an air inlet and an air outlet, the hydrogen supply device is communicated with the air inlet of the ionization cavity so as to introduce hydrogen into the ionization cavity, the discharge electrode is used for releasing high-speed electrons into the ionization cavity, and the negative ion emitter is used for transmitting the hydrogen in the ionization cavity out of the air outlet.

2. The hydrogen generation apparatus according to claim 1, further comprising a hydrogen concentration detection mechanism provided on a pipe connecting the hydrogen supply device and the ionization chamber.

3. The hydrogen-producing apparatus according to claim 2, wherein the hydrogen concentration detection mechanism is disposed near an inlet of the ionization chamber.

4. The hydrogen generation apparatus according to claim 2, further comprising a control device electrically connected to the hydrogen concentration detection mechanism and the negative ion generation device, wherein the control device controls the negative ion generation device to be turned on when the hydrogen concentration detection mechanism detects that the hydrogen concentration is not less than a set value.

5. The hydrogen generation apparatus according to claim 4, wherein the control device further adjusts the operating power of the negative ion generation device according to the hydrogen concentration detected by the hydrogen concentration detection mechanism.

6. The hydrogen production equipment as claimed in any one of claims 1 to 5, further comprising a gas-water separation device, wherein the gas-water separation device is arranged on a pipeline of the hydrogen supply device communicated with the ionization chamber, and the gas-water separation device is used for separating hydrogen and moisture.

7. The hydrogen-producing apparatus according to claim 6, wherein the gas-water separating device includes a separation chamber, and a waterproof permeable membrane and a water vapor filter element disposed in the separation chamber, the separation chamber is provided with a separation inlet for communicating with the hydrogen gas supplying device and a separation outlet for communicating with the ionization chamber, the waterproof permeable membrane is disposed at a side close to the separation inlet, and the water vapor filter element is disposed at a side close to the separation outlet.

8. The hydrogen production equipment as claimed in any one of claims 1 to 5 and 7, wherein the hydrogen supply device comprises a water electrolysis chamber and a water storage container, the water storage container is communicated with the water electrolysis chamber to provide water for the water electrolysis chamber, the water electrolysis chamber is provided with a hydrogen outlet, and the hydrogen outlet is communicated with the air inlet of the ionization chamber.

9. The hydrogen-generation facility of claim 8, further comprising at least one of the following detectors:

the liquid level detector is used for detecting the height of the liquid level of the water storage container;

the TDS detector is used for detecting the water quality condition in the water storage container;

the inclination detector is used for detecting the inclination condition of the water storage container;

the flow velocity detector is used for detecting the flow velocity of liquid in a liquid pipeline of the water storage container leading to the water electrolysis chamber;

a temperature detector for detecting a temperature within the water electrolysis chamber; and

and a power supply voltage detector for detecting the power supply voltage.

10. The hydrogen production plant according to claim 9, further comprising an alarm electrically connected to at least one of the detectors, wherein the alarm gives an alarm when a detection result of any one of the detectors electrically connected to the alarm exceeds a set range.

Images