CN116688299A - Intelligent oxyhydrogen breathing machine with water magnetizing device - Google Patents

Abstract

The application discloses an intelligent oxyhydrogen breathing machine with a water magnetizing device, which comprises: the system comprises a supporting frame, a water storage system, an electrolysis module and an electric control system; the water storage system comprises a raw material water tank and a magnetized water tank; the raw material water tank is fixedly arranged in the outer shell and fixedly arranged at the top of the inner support frame; raw material water is contained in the raw material water tank; the raw material water tank is communicated with the magnetized water tank through the magnetic polarization module; the electrolysis module is arranged in the inner supporting frame and is used for separating oxygen and hydrogen from the electrolysis water in the raw material water tank; the electric control system comprises a built-in power supply, a control circuit board and a control panel; the built-in power supply is electrically connected with the control panel through the control circuit board. The magnetic polarization module comprises a magnetized water pump and a permanent magnet. The application converts the electrolysis raw water into magnetized water by adding the magnetic polarization module, improves the hydrogen production efficiency of the product and reduces the hydrogen production electricity price cost.

Description

Intelligent oxyhydrogen breathing machine with water magnetizing device

Technical Field

The application belongs to the technical field of hydrogen production, and particularly relates to an intelligent oxyhydrogen breathing machine with a water magnetizing device.

Background

Oxyhydrogen breathing machine is one of the important ways of taking in hydrogen by human body, and human body can remove harmful free radical and strengthen the ability of resisting oxidation and inflammation by taking in hydrogen, and is beneficial to sub-health of human body and recovery of various diseases, and the hydrogen medical technology taking hydrogen absorption as a core is becoming one of the important directions of medical development. The main hydrogen production technology of the existing oxyhydrogen breathing machine is divided into three types, namely: hydrogen storage tank type, hydride hydrolysis reaction type and proton exchange membrane electrolysis water reaction type. The hydrogen storage tank type is similar to an oxygen tank in the way of absorbing oxygen, and has the problems of unsafe hydrogen storage, huge hydrogen storage tank, difficult transportation and the like; the hydride hydrolysis reaction type has the problems of low service life, strong corrosiveness of byproduct hydroxide, difficult treatment and the like; the proton exchange membrane electrolyzed water reaction type hydrogen production is clean, safe, free of toxic and strong corrosive byproducts, and is a main core technology adopted by the existing oxyhydrogen breathing machine in the market.

The oxyhydrogen breathing machine taking proton exchange membrane water electrolysis technology as a core mainly comprises: the hydrogen production technology of the conventional oxyhydrogen breathing machine mainly adopts a PEM (proton exchange membrane) electrolytic tank to directly electrolyze pure water to generate oxygen and hydrogen, but the conventional scheme has low hydrogen production efficiency, so that the problem of high electricity price cost is to be solved.

Disclosure of Invention

The application aims to provide an intelligent oxyhydrogen breathing machine with a water magnetizing device, so as to solve the problems and achieve the purpose of improving the hydrogen production efficiency of products.

In order to achieve the above object, the present application provides the following solutions:

an intelligent oxyhydrogen breathing machine with a water magnetizing device, comprising:

the support frame comprises an outer shell and an inner support frame;

a water storage system; the water storage system comprises a raw material water tank and a magnetized water tank; the raw material water tank is fixedly arranged in the outer shell and fixedly arranged at the top of the inner support frame; raw material water is contained in the raw material water tank; the raw water tank is communicated with the magnetized water tank through a magnetic polarization module;

the electrolysis module is arranged in the inner supporting frame and is used for separating oxygen and hydrogen from the electrolysis water in the raw material water tank;

the electronic control system comprises a built-in power supply, a control circuit board and a control panel; the built-in power supply is electrically connected with the control panel through the control circuit board.

The magnetic polarization module comprises a magnetized water pump and a permanent magnet; the electrolyte outlet on the bottom surface of the raw material water tank is communicated with the magnetized water pump through a water pipe; the magnetized water pump is communicated with the permanent magnet through a bent pipe, and the permanent magnet is communicated with the top of the magnetized water tank through a bent pipe; the bottom of the magnetized water tank is communicated with a magnetized water inlet on the bottom surface of the raw material water tank through a water pipe.

The top surface of the raw material water tank is communicated with an external water adding pipe; the external water adding pipe is embedded at the top of the outer shell; a steam-water separation chamber is arranged at one corner of the inner side of the raw material water tank, an electrolyte backflow outlet is formed in the bottom of the steam-water separation chamber, and the electrolyte backflow outlet is communicated with the electrolyte backflow inlet through a water pipe; the electrolyte backflow inlet is formed in the top surface of the raw material water tank;

the bottom center of the raw material water tank is also provided with a magnetized water outlet which is communicated with the water inlet of the electrolysis module through a water pipe.

The top surface of the raw material water tank is also provided with a hydrogen inlet, a hydrogen outlet, an oxygen outlet and an oxygen inlet; the hydrogen outlet and the hydrogen outlet are both arranged above the steam-water separation chamber.

The inner cavity of the raw material water tank is also provided with a water level detector; a TDS sensor is arranged on the bottom surface of the raw material water tank; the top surface and the bottom surface of the raw material water tank are provided with a plurality of reserved interfaces; the water level detector and the TDS sensor are electrically connected with the control circuit board.

The permanent magnets are N52 pipe type neodymium iron boron permanent magnets, and three permanent magnets are arranged in series.

The electrolysis module comprises an ion exchange resin box and a PEM (proton exchange membrane) electrolysis cell; the input end of the ion exchange resin box is communicated with a liquid pump through a water pipe, and the liquid pump is communicated with the magnetized water outlet through a water pipe; the output end of the ion exchange resin box is communicated with the water inlet of the PEM electrolytic tank through a water pipe.

Two hydrogen generation ports and an oxygen generation port are formed in the PEM electrolytic tank; the hydrogen generation port is communicated with the hydrogen inlet through an air pipe; the oxygen generating port is communicated with the oxygen inlet through an air pipe; and a temperature sensor is also arranged on the PEM electrolytic tank and is electrically connected with the built-in power supply.

The inner support frame comprises two side support frames, a power supply support frame and a bending support frame; the tops of the two side support frames are fixedly connected with the magnetized water tank through a base support table; the bending support frame is fixedly connected with the raw material water tank through the base support table; the middle part of the top surface of the bending support frame, and the top parts of the support frames on two sides are provided with hollowed-out areas for water pipe installation.

The bottoms of the two side support frames are also provided with heat dissipation grooves, and fans are arranged in the heat dissipation grooves; the fan is disposed opposite the PEM electrolyser end of the electrolyser module.

The built-in power supply and the control circuit board are fixedly arranged on the power supply supporting frame, and the control panel is embedded in the top surface of the outer shell.

Compared with the prior art, the application has the following advantages and technical effects: the application converts the electrolysis raw water into magnetized water by adding the magnetic polarization module, improves the hydrogen production efficiency of the product and reduces the hydrogen production electricity price cost.

Drawings

For a clearer description of an embodiment of the application or of the solutions of the prior art, the drawings that are needed in the embodiment will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the application, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art:

FIG. 1 is a schematic diagram of the overall external structure;

FIG. 2 is a schematic view of an internal structure;

FIG. 3 is a schematic view of an inner support frame arrangement;

FIG. 4 is a schematic view of the structure of the inner support frame;

FIG. 5 is a schematic diagram of the top surface structure of the raw material water tank;

FIG. 6 is a schematic diagram of the bottom surface structure of the raw material water tank;

FIG. 7 is a schematic view of the internal structure of the raw material water tank;

FIG. 8 is a schematic workflow diagram;

FIG. 9 is a graph of hydrogen production versus amount;

FIG. 10 is a graph of magnetic field magnetization contrast;

FIG. 11 is a graph showing the relationship between interelectrode voltage and magnetic induction;

FIG. 12 is a graph of inter-electrode current versus magnetic induction;

wherein, 1, the outer chassis; 2. an inner support; 3. a raw material water tank; 4. a magnetized water tank; 5. magnetizing a water pump; 6. a built-in power supply; 7. a control circuit board; 8. a control panel; 9. a PEM electrolyzer; 21. a side support; 22. a power supply support; 23. bending the supporting frame; 24. a base support; 25. a fan; 31. an external water supply pipe; 32. a steam-water separation chamber; 33. an electrolyte return outlet; 34. an electrolyte backflow inlet; 35. a hydrogen inlet; 36. an oxygen inlet; 37. a hydrogen outlet; 38. an oxygen outlet; 39. an electrolyte outlet; 310. a magnetized water inlet; 311. a magnetized water outlet; 312. a water level detector; 313. a TDS sensor; 51. a permanent magnet; 91. an ion exchange resin cartridge; 92. a liquid pump; 93. a hydrogen generation port; 94. an oxygen generating port.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description.

An intelligent oxyhydrogen breathing machine with a water magnetizing device, comprising:

the support frame comprises an outer shell 1 and an inner support frame 2;

a water storage system; the water storage system comprises a raw material water tank 3 and a magnetized water tank 4; the raw material water tank 3 is fixedly arranged in the outer shell 1 and fixedly arranged at the top of the inner support frame 2; the raw material water tank 3 is internally provided with raw material water; the raw material water tank 3 is communicated with the magnetized water tank 4 through a magnetic polarization module;

the electrolysis module is arranged in the inner supporting frame 2 and is used for separating oxygen and hydrogen from the electrolysis water in the raw material water tank 3;

the electronic control system comprises a built-in power supply 6, a control circuit board 7 and a control panel 8; the built-in power supply 6 is electrically connected with the control panel 8 through the control circuit board 7.

In one embodiment of the present application, the magnetized water tank 4 has a u-shaped structure, and the magnetized water tank 4 is disposed around the raw water tank 3.

Furthermore, the bottoms of the two ends of the magnetized water tank 4 can be connected with a tap through a water pipe, and the tap penetrates through the side wall of the outer shell 1; the tap can directly take out the magnetized water.

The magnetic polarization module comprises a magnetized water pump 5 and a permanent magnet 51; an electrolyte outlet 39 on the bottom surface of the raw material water tank 3 is communicated with the magnetized water pump 5 through a water pipe; the magnetized water pump 5 is communicated with the permanent magnet 51 through a bent pipe, and the permanent magnet 51 is communicated with the top of the magnetized water tank 4 through a bent pipe; the bottom of the magnetized water tank 4 is communicated with a magnetized water inlet 310 at the bottom of the raw water tank 3 through a water pipe.

The top surface of the raw material water tank 3 is communicated with an external water adding pipe 31; the external water adding pipe 31 is embedded at the top of the outer shell 1; a steam-water separation chamber 32 is arranged at one corner of the inner side of the raw material water tank 3, an electrolyte backflow outlet 33 is formed in the bottom of the steam-water separation chamber 32, and the electrolyte backflow outlet 33 is communicated with an electrolyte backflow inlet 34 through a water pipe; the electrolyte backflow inlet 34 is formed in the top surface of the raw material water tank 3;

the bottom center of the raw material water tank 3 is also provided with a magnetized water outlet 311, and the magnetized water outlet 311 is communicated with a water inlet of the electrolysis module through a water pipe.

In one embodiment of the present application, the external water supply pipe 31 is used to supply the raw material water tank 3 with the electrolytic raw material water for the ventilator; after the electrolytic raw material water is added, a magnetic polarization module is started, the electrolytic raw material water is pumped out of an electrolyte outlet 39 through a magnetized water pump 5, the electrolytic raw material water passes through N52 tubular NdFeB permanent magnets which sequentially pass through 3, a water pipe passes out of the permanent magnets 51 and finally is connected into a communication port at the top of a magnetized water tank 4, and magnetized water can flow back to a magnetized water inlet 310 at the bottom surface of the raw material water tank 3 through the communication port at the bottom of the magnetized water tank 4; at this time, the electrolyzed raw water in the raw water tank 3 is converted into magnetized water;

further, opening the magnetized water outlet 311 lets magnetized water into the electrolytic module.

In one embodiment of the present application, the permanent magnet is preferably a 10000GSN52 tube type NdFeB permanent magnet.

The top surface of the raw material water tank 3 is also provided with a hydrogen inlet 35, a hydrogen outlet 37, an oxygen outlet 38 and an oxygen inlet 36; the hydrogen outlet 35 and the hydrogen outlet 37 are both opened above the steam-water separation chamber 32.

The inner cavity of the raw material water tank 3 is also provided with a water level detector 312; a TDS sensor 313 is arranged on the bottom surface of the raw material water tank 3; the top surface and the bottom surface of the raw material water tank 3 are provided with a plurality of reserved interfaces; the water level detector 312 and the TDS sensor 313 are electrically connected to the control circuit board 7.

In one embodiment of the application, a water level detector 312 is used to monitor the water level in the feed water tank 3 to prevent dry fire damage caused by the non-water feed to the PEM electrolyzer 9.

In one embodiment of the application, the TDS sensor 313 is used to detect water quality and prevent PEM electrolyzer 9 proton exchange membrane poisoning.

The permanent magnet 51 is an N52 tube type neodymium iron boron permanent magnet, and three permanent magnets 51 are arranged in series.

The electrolysis module comprises an ion exchange resin cartridge 91 and a PEM electrolyzer 9; the input end of the ion exchange resin box 91 is communicated with a liquid pump 92 through a water pipe, and the liquid pump 92 is communicated with a magnetized water outlet 311 through a water pipe; the output end of the ion exchange resin box 91 is communicated with the water inlet of the PEM electrolytic tank 9 through a water pipe.

In one embodiment of the application, the magnetized water outlet 311 is driven by the liquid pump 92 to pump the magnetized water into the ion exchange resin box 91, and after the anions and cations in the water are removed, the magnetized water is led into the water inlet of the PEM electrolytic tank 9; the PEM electrolyzer 9 electrolyzes the magnetized water to generate hydrogen and oxygen with water; at this time, hydrogen is introduced into the hydrogen inlet 35 through the gas pipe to remove moisture; oxygen is introduced into the oxygen inlet 36 and is directly discharged from the oxygen outlet 38.

Further, a steam-water separation chamber 32 is arranged at one corner of the inner side of the raw material water tank 3, and the steam-water separation chamber 32 is used for separating water in the gas so as to precipitate the water; after the water is precipitated, the water flows back into the raw water tank 3 through an electrolyte backflow outlet 33 arranged at the bottom of the steam-water separation chamber 32 for continuous use.

Further, the hydrogen gas from which the moisture is removed is discharged from the hydrogen gas outlet 37; the hydrogen inlet 35 and the hydrogen outlet 37 are arranged above the steam-water separation chamber 32 and are not communicated with the inner cavity of the raw material water tank 3.

Two hydrogen generation ports 93 and an oxygen generation port 94 are formed in the PEM electrolytic tank 9; the hydrogen generation port 93 communicates with the hydrogen inlet 35 through a gas pipe; the oxygen generating port 94 communicates with the oxygen inlet 36 through a gas pipe; the PEM electrolyzer 9 is also provided with a temperature sensor electrically connected to the internal power supply 6.

The inner support frame 2 comprises two side support frames 21, a power supply support frame 22 and a bending support frame 23; the tops of the two side support frames 21 are fixedly connected with the magnetized water tank 4 through a base support table 24; the bending support frame 23 is fixedly connected with the raw material water tank 3 through a base support table 24; the middle part of the top surface of the bending support frame 23, and the top parts of the support frames 21 on two sides are provided with hollowed-out areas for water pipe installation.

The bottoms of the two side support frames 21 are also provided with heat dissipation grooves, and fans 25 are arranged in the heat dissipation grooves; a fan 25 is arranged opposite the end of the PEM electrolyser 9 of the electrolyser module.

The built-in power supply 6 and the control circuit board 7 are fixedly arranged on the power supply supporting frame 22, and the control panel 8 is embedded in the top surface of the outer shell 1.

In one embodiment of the application, a fan 25 is used to dissipate heat from the PEM electrolyzer 9.

In one embodiment of the present application, the control circuit board 7 is electrically connected to the built-in power supply 6 through an adapter.

In one embodiment of the application, the control circuit board 7 is used for controlling the whole intelligent oxyhydrogen breathing machine, is connected with water level detection, TDS detection, temperature detection, magnetic polarization module water pump, water pump and control panel for overall control, and is powered by 220V alternating current input connected with a power adapter.

In one embodiment of the application, as shown in FIG. 9;

distilled water is respectively introduced into the intelligent oxyhydrogen breathing machine without the magnetic polarization module and the magnetic polarization module to produce hydrogen, the hydrogen production amounts of the two intelligent breathing machines are respectively compared by adopting an MFM-50 explosion-proof gas mass flowmeter, the hydrogen production rate of the oxyhydrogen breathing machine after the magnetic field pre-polarization treatment in the figure 1 is obviously improved, and the hydrogen production rate of the distilled water after the 30000GS magnetic field polarization treatment is improved by about 15 percent through a PEM electrolytic tank of the oxyhydrogen breathing machine.

In one embodiment of the present application, as shown in FIG. 10:

the graph shows the change curve of the conductivity with the magnetization time after the distilled water is magnetized by different magnetic fields at 20 ℃, and the graph shows that the conductivity is in an ascending trend with the magnetization time according to the graph in fig. 2, and the final conductivity can be improved by about 2-3 times after the distilled water is magnetized for about 35min, wherein the magnetization effect of 10000GS magnetic field is most remarkable.

In one embodiment of the present application, as shown in fig. 11 and 12:

distilled water subjected to polarization treatment of different magnetic fields is input into an internal PEM (proton exchange membrane) electrolytic tank through a water tank of an oxyhydrogen breathing machine, meanwhile, a power supply is controlled to provide 7V 20A output current, a fitting curve of the actual interelectrode voltage change of the electrolytic tank is obtained, as shown in the figure 3, and the actual interelectrode voltage of the PEM electrolytic tank in the breathing machine is in a descending trend along with the increase of the magnetic field intensity; the fitting curve of the change of the plate current density of the electrolytic cell is shown in fig. 4, and the actual plate current density of the PEM electrolytic cell in the oxyhydrogen breathing machine is in an ascending trend along with the increase of the magnetic field intensity; the method shows that with the increase of the magnetic field intensity, the diffusion coefficient of distilled water ions in the breathing machine is increased, and the overpotential of the resistance is reduced, so that the actual interelectrode voltage of the electrolytic cell is reduced, the current density of an actual polar plate of the electrolytic cell is improved, and the hydrogen production efficiency is effectively improved.

In the description of the present application, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present application, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

The above embodiments are only illustrative of the preferred embodiments of the present application and are not intended to limit the scope of the present application, and various modifications and improvements made by those skilled in the art to the technical solutions of the present application should fall within the protection scope defined by the claims of the present application without departing from the design spirit of the present application.

Claims (10)

1. An intelligent oxyhydrogen breathing machine with a water magnetizing device, which is characterized by comprising:

the support frame comprises an outer shell (1) and an inner support frame (2);

a water storage system; the water storage system comprises a raw material water tank (3) and a magnetized water tank (4); the raw material water tank (3) is fixedly arranged in the outer shell (1) and fixedly arranged at the top of the inner supporting frame (2); raw material water is contained in the raw material water tank (3); the raw material water tank (3) is communicated with the magnetized water tank (4) through a magnetic polarization module;

the electrolysis module is arranged in the inner supporting frame (2) and is used for separating oxygen and hydrogen from the electrolysis water in the raw material water tank (3);

the electronic control system comprises a built-in power supply (6), a control circuit board (7) and a control panel (8); the built-in power supply (6) is electrically connected with the control panel (8) through the control circuit board (7);

the magnetic polarization module comprises a magnetized water pump (5) and a permanent magnet (51); an electrolyte outlet (39) at the bottom surface of the raw material water tank (3) is communicated with the magnetized water pump (5) through a water pipe; the magnetized water pump (5) is communicated with the permanent magnet (51) through a bent pipe, and the permanent magnet (51) is communicated with the top of the magnetized water tank (4) through a bent pipe; the bottom of the magnetized water tank (4) is communicated with a magnetized water inlet (310) at the bottom surface of the raw material water tank (3) through a water pipe.

2. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 1, characterized in that: the top surface of the raw material water tank (3) is communicated with an external water adding pipe (31); the external water adding pipe (31) is embedded at the top of the outer shell (1); a steam-water separation chamber (32) is arranged at one corner of the inner side of the raw material water tank (3), an electrolyte backflow outlet (33) is formed in the bottom of the steam-water separation chamber (32), and the electrolyte backflow outlet (33) is communicated with the electrolyte backflow inlet (34) through a water pipe; the electrolyte backflow inlet (34) is formed in the top surface of the raw material water tank (3);

the bottom center of the raw material water tank (3) is also provided with a magnetized water outlet (311), and the magnetized water outlet (311) is communicated with the water inlet of the electrolysis module through a water pipe.

3. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 2, characterized in that: the top surface of the raw material water tank (3) is also provided with a hydrogen inlet (35), a hydrogen outlet (37), an oxygen outlet (38) and an oxygen inlet (36); the hydrogen outlet (35) and the hydrogen outlet (37) are both arranged above the steam-water separation chamber (32).

4. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 2, characterized in that: a water level detector (312) is also arranged in the inner cavity of the raw material water tank (3); a TDS sensor (313) is arranged on the bottom surface of the raw material water tank (3); a plurality of reserved interfaces are arranged on the top surface and the bottom surface of the raw material water tank (3); the water level detector (312) and the TDS sensor (313) are electrically connected with the control circuit board (7).

5. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 1, characterized in that: the permanent magnets (51) are N52-tube-type neodymium iron boron permanent magnets, and three permanent magnets (51) are arranged in series.

6. An intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 3, characterized in that: the electrolysis module comprises an ion exchange resin box (91) and a PEM electrolysis cell (9); the input end of the ion exchange resin box (91) is communicated with a liquid pump (92) through a water pipe, and the liquid pump (92) is communicated with the magnetized water outlet (311) through a water pipe; the output end of the ion exchange resin box (91) is communicated with the water inlet of the PEM electrolytic tank (9) through a water pipe.

7. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 6, characterized in that: two hydrogen generation ports (93) and an oxygen generation port (94) are formed in the PEM electrolytic tank (9); the hydrogen generation port (93) is communicated with the hydrogen inlet (35) through a gas pipe; the oxygen generating port (94) is communicated with the oxygen inlet (36) through an air pipe; and a temperature sensor is also arranged on the PEM electrolytic tank (9), and the temperature sensor is electrically connected with the built-in power supply (6).

8. An intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 3, characterized in that: the inner support frame (2) comprises two side support frames (21), a power supply support frame (22) and a bending support frame (23); the tops of the two side support frames (21) are fixedly connected with the magnetized water tank (4) through a base support table (24); the bending support frame (23) is fixedly connected with the raw material water tank (3) through the base support table (24); the middle part of the top surface of the bending support frame (23), and the top parts of the support frames (21) on two sides are provided with hollowed-out areas for water pipe installation.

9. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 8, characterized in that: the bottoms of the two side support frames (21) are also provided with heat dissipation grooves, and fans (25) are arranged in the heat dissipation grooves; the fan (25) is arranged opposite to the end of the PEM electrolytic cell (9) of the electrolytic module.

10. The intelligent oxyhydrogen breathing machine with a water magnetizing device according to claim 8, characterized in that: the built-in power supply (6) and the control circuit board (7) are fixedly arranged on the power supply supporting frame (22), and the control panel (8) is embedded on the top surface of the outer casing (1).