JP2024008756A - In-situ photocatalyst system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system which can perform photocatalyst treatment of water hardly penetrated by light such as odorous black water and sludge water.

SOLUTION: An in-situ photocatalyst system includes: a light source module 3 for provision of a light source; and a light fiber for carrying a catalyst. The light fiber is joined on one end to a light emitting port of the light source module. The light fiber is put on the other end into water. The system can effectively solve a problem that sunlight dose not directly strike on odorous black water and sludge, and can perform in-situ pollution restoration with clean energy in an environmentally friendly way.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2024,JPO&INPIT

Description

The present invention relates to the technical field of photocatalysis, and specifically to in-situ photocatalyst systems.

The black and smelly water is a biochemical phenomenon; when water is seriously contaminated with organic matter, the rate of oxygen consumption in the water is greater than the rate of reoxygenation due to aerobic decomposition of organic matter, and the oxygen in the water is Deficiency occurs, resulting in incomplete and slow decomposition of organic matter, and odorous substances such as hydrogen sulfide, ammonia, and mercaptans are produced in the process of anaerobic biodegradation, as well as black matter. formation, which causes the water to become black and smelly.
Water becoming black and smelly is a serious water pollution phenomenon, which can completely lose the ability to use water,
It has a negative impact on the landscape and human life and health. Photocatalytic treatment of black-smelling water and sludge is difficult because it cannot solve the problem of light passing through the black-smelling water and sludge.On the other hand, chemical treatment tends to generate new pollutants. Easy to affect the ecosystem.

In order to solve the above technical problems, the present invention provides an in-situ photocatalytic system.

The technical solutions of the present invention are as follows. An in-situ photocatalytic system,
a light source module for providing a light source; and an optical fiber for supporting a catalyst; one end of the optical fiber is butted against a light exit of the light source module, and the other end of the optical fiber is submerged in water;
The catalyst is one of TiO ₂ and BiO ₂ , and the TiO ₂ is nitrogen-doped TiO ₂ .
The catalyst is supported on the optical fiber by one of immersion calcination (strongly heating a substance to cause dehydration and decomposition to remove volatile components) and gel coating. Ru. _TiO2 can only be excited in the ultraviolet range, while nitrogen-doped _TiO2 can be excited in sunlight, so the scope of application of nitrogen-doped _TiO2 is wider when used in natural environments.
According to one aspect of the present invention, the water is black-smelling water or sludge water.
According to one aspect of the present invention, the optical fiber adopts the following two forms.
1) In the case of the dark-smelling water, an optical fiber is placed in the dark-smelling water in a shape that imitates aquatic plants. By making the optical fiber into a shape that imitates aquatic plants, the impact on the ecosystem is reduced, and by making it a tree that emits light at night, it improves the appearance and practicality.
2) In the case of the sludge water, optical fibers are dispersed in the sludge of the sludge water in the form of a dot matrix. By using something like a metal casing to send it into the sludge, then taking out the metal casing and arranging the optical fibers radially in the sludge, we solved the problem of sunlight not directly hitting the sludge. Improve water treatment efficiency and promote photodegradation of pollutants.
According to one aspect of the present invention, the light source module uses a near-field light source device or a float light source device, the float light source device includes a light source unit and a float stabilizer, and the near-field light source device and the light source unit are both self-contained. It is either a light emitting source or a concentrator.
The in-situ photocatalytic system is selected according to the actual environmental needs of black-smelling water and sludge water.
According to one aspect of the present invention, the float stabilizer includes a housing, two sets of transmission rings, and a center rod,
The housing is hollow inside, and is provided with a central cylindrical body in the center for swinging the center rod, and the two sets of transmission rings are respectively provided on the inner top surface and the inner bottom surface of the housing, and two Each set of transmission rings is rotatably mounted on a central cylinder,
A mounting plate is provided at the center of the center cylinder, and a socket is provided at the center of the mounting plate, and is rotatably fitted to a ball provided on the center rod.
A connection stand connected to the light source unit is provided at one end of the center rod, a counterweight is provided at the other end of the center rod and screwed to the center rod, and an optical fiber is connected to the center rod. A penetrating communication hole is provided,
The connection base is connected to the housing via a plurality of sets of first airbags arranged radially, and each of the plurality of sets of first airbags has one end connected to the connection base and the other end connected to the housing. ,
At least one set of drive gears is rotatably mounted on the inner wall of the housing located between the two sets of transmission rings, and the transmission ring is provided with a toothed disc meshing with said drive gears.
According to the configuration of the float stabilizer, it is possible to rotate clockwise and counterclockwise using two sets of transmission rings under a single drive, and thereby the two sets of transmission rings rotate. By moving, a stable dynamic balance is achieved and the risk of the float light source device tipping over is avoided.
In one preferred aspect of the present invention, a plurality of sets of branch pipes are provided on the side wall of the housing and correspond to the first airbags on a one-to-one basis, and the branch pipes are provided on the opposite side of the first airbag via a tube. connected to the first airbag,
An annular groove is provided in the side wall of the transmission ring, and a pair of second air bags are provided in the upper and lower parts of the diverter pipe, respectively, and fit into the corresponding annular grooves;
A countersink is provided in the transmission ring located at the inner bottom of the annular groove and corresponds to each second airbag on a one-to-one basis, a counterweight slider is slidably provided in the countersink, and the counterweight slider One side of the counterweight slider is connected to the inner bottom of the countersink via a spring, an arc-shaped seat is provided on the other side of the counterweight slider, and a guide rod of the arc-shaped seat is provided in the transmission ring on both sides of the countersink. a pair of guide grooves each slidably connected to the guide grooves;
an elastic ring is provided in an annular groove between the arcuate seat and the second airbag, and the elastic ring is slidably connected to an end surface of the second airbag;
The housing is provided with a cover that covers each tube, and at least one of a solar panel or a battery is laid on the surface of the cover, and the housing is provided with a drive that is butted against the shaft of the drive gear. A motor is provided, said drive motor being connected to a solar panel or battery via a relay.
Based on the float stabilizer, multiple sets of diverter pipes are arranged to cooperate with the first airbag,
By improving the internal structure of the transmission ring, multiple sets of counterweight sliders and other members are used to adjust the center of gravity of the transmission ring when large waves occur on the water surface, thereby preventing the float stabilizer from overturning. Significantly reduce risk.
In another preferred aspect of the present invention, the side wall of the housing is provided with one-to-one support for the first airbag.
There are multiple sets of stabilizers that correspond to
The stabilizer includes a rotating rod, a rotating bush, and a third airbag, and the rotating bush is rotatably connected to a fixed block provided on a side wall of the housing, and the rotating bush is rotatably connected to a fixed block provided on a side wall of the housing. at least one set of restriction ribs are provided, a pivot rod is slidably engaged with the pivot bushing, and an inner wall of the pivot bush is provided with a limitation groove that engages with the limitation ribs;
One end of the third airbag is rotatably connected to one end of a rotating rod, the other end of the rotating rod is sheathed with at least one set of discs, and the other end of the third airbag is connected to a tube. connected to the corresponding first airbag via the
A plurality of sets of the drive gears are provided and correspond to the first airbag on a one-to-one basis, and an output shaft of the drive gear passes through the housing, is connected to the first bevel gear, and is connected to the rotation bush. teeth,
A second bevel gear that meshes with the first bevel gear to transmit transmission is provided,
At least one set of the fixed blocks is provided with a ring motor connected to a rotating bush, at least one of a solar panel or a battery is installed in the housing, and the ring motor is connected to the solar panel through a relay. Or connected to a battery.
By arranging multiple sets of stabilizers based on the float stabilizer that cooperate with the first airbag, the number of drive motors to be arranged is significantly reduced due to the interlocking of the stabilizer and the transmission ring, and the disc rotates underwater. By moving, a stable dynamic balance is achieved, and the third
By installing components such as airbags, it effectively solves the problem of the stabilizer disc touching the bottom or separating from the water surface due to the water depth being too small when large waves occur on the water surface. to avoid.

The beneficial effects of the present invention are as follows.
(1) The in-situ photocatalyst system of the present invention uses a light source module and an optical fiber in combination to effectively solve the problem of sunlight not directly hitting dark-smelling water and sludge, and photodecomposes pollutants. In-situ pollution remediation can be done in an environmentally friendly manner using clean energy.
(2) The in-situ photocatalyst system of the present invention provides multiple configurations, so the in-situ photocatalyst system can be selected according to the actual environmental needs of black-smelling water and sludge water.
(3) In the in-situ photocatalyst system of the present invention, by providing a float stabilizer, the stability of the arrangement of the float light source device on the water surface is improved, and the light collection efficiency of the mounted light collector is affected by the wave motion of the water surface. In addition, the risk of the float light source device being overturned is also effectively avoided.

1 is a schematic diagram of an in-situ photocatalyst system according to Example 1 of the present invention. FIG. 2 is a schematic diagram of an in-situ photocatalyst system according to Example 2 of the present invention. It is a schematic diagram of the in-situ photocatalyst system of Example 3 of this invention. FIG. 4 is a schematic diagram of an in-situ photocatalyst system according to Example 4 of the present invention. It is a schematic diagram of the in-situ photocatalyst system of Example 5 of this invention. FIG. 6 is a schematic diagram of an in-situ photocatalyst system according to Example 6 of the present invention. It is a schematic diagram of the in-situ photocatalyst system of Example 7 of this invention. It is a schematic diagram of the in-situ photocatalyst system of Example 8 of this invention. FIG. 6 is a schematic diagram of a float light source device according to Examples 5 and 6 of the present invention. FIG. 6 is a schematic structural diagram of a float stabilizer according to embodiments 5 and 6 of the present invention. FIG. 7 is a schematic partial cross-sectional view of a float stabilizer according to Examples 5 and 6 of the present invention. FIG. 6 is a structural schematic diagram of a transmission ring of a float stabilizer according to embodiments 5 and 6 of the present invention. FIG. 7 is a schematic diagram of an internal structure of an example of a transmission ring of a float stabilizer according to Examples 5 and 6 of the present invention. FIG. 7 is another schematic diagram of the internal structure of the transmission ring of the float stabilizer according to Examples 5 and 6 of the present invention. FIG. 7 is a schematic diagram of the structure of the flow divider pipe of the float stabilizer according to Examples 5 and 6 of the present invention. FIG. 7 is a schematic diagram of a float light source device according to Examples 7 and 8 of the present invention. FIG. 7 is a schematic structural diagram of a float stabilizer according to embodiments 7 and 8 of the present invention. FIG. 7 is a schematic partial cross-sectional view of a float stabilizer according to Examples 7 and 8 of the present invention. FIG. 7 is a schematic diagram of the stabilizer structure of the float stabilizer according to Examples 7 and 8 of the present invention. FIG. 7 is a structural schematic diagram of a rotating rod of a float stabilizer according to embodiments 7 and 8 of the present invention. FIG. 7 is a structural schematic diagram of a rotary bush of a float stabilizer according to embodiments 7 and 8 of the present invention. FIG. 7 is a structural schematic diagram of the center rod of the float stabilizer according to Examples 5, 6, 7, and 8 of the present invention.

Hereinafter, the present invention will be further described with reference to specific implementations, in order to better demonstrate the advantages of the present invention.
Example 1
As shown in FIG. 1, the in-situ photocatalyst system includes a light source module for providing a light source and an optical fiber for supporting a catalyst, one end of the optical fiber is butted against the light exit of the light source module, and the optical fiber The other end goes into the water,
The light source module uses a near-field light source device 1, specifically a self-luminous light source, and the catalyst is nitrogen-doped T.
_iO2 , nitrogen-doped _TiO2 is supported on the optical fiber by gel coating method,
The water is sludge water, and in the case of sludge water, optical fibers are dispersed in the sludge in the form of a dot matrix.
The method for forming the dot matrix is as follows. Connect one end of the optical fiber to a self-luminous light source, put the other end of the optical fiber inside the metal casing and send it into the sludge, then take out the metal casing and in this way, make the optical fibers radially arranged in the sludge. .

Example 2
This example is the same as Example 1 except that, as shown in FIG. 2, the water is black-smelling water, and in the case of black-smelling water, the optical fiber is arranged in the dark-smelling water in a shape that imitates aquatic plants. .

Example 3
As shown in FIG. 3, this example is the same as Example 1 except that the light source module uses a nearby light source device 1, specifically a condenser.

Example 4
As shown in FIG. 4, this embodiment is the same as the second embodiment except that the light source module uses a near-field light source device 1, specifically a condenser.

Example 5
This example is the same as Example 3 except for the following. As shown in FIGS. 5 and 9, the light source module uses a float light source device 2, and the float light source device 2 includes a light source unit 3 and a float stabilizer 4, and the light source unit 3 is specifically a light condenser. .
As shown in FIGS. 10 and 11, the float stabilizer 4 includes a housing 41, two sets of transmission rings 42, and a center rod 43. The housing 41 is hollow inside, and the center rod 43 swings in the center. A central cylindrical body 411 for movement is provided, two sets of transmission rings 42 are respectively provided on the inner top surface and the inner bottom surface of the housing 41, and the two sets of transmission rings 42 are connected to the center cylinder through their inner walls. It is rotatably mounted on the body 411.
As shown in FIG. 22, a mounting plate 44 is provided at the center of the central cylindrical body 411, and a socket rotatably fitted to a ball 431 provided on the center rod 43 at the center of the mounting plate 44. 441 is provided.
As shown in FIG. 11, a connection stand 432 connected to the light source unit 3 is provided at the upper end of the center rod 43, and a counterweight 433 is screwed to the center rod 43 at the lower end of the center rod 43.
is provided, and the counterweight 433 has a plurality of center rods 4 according to the needs of actual use.
3, the counterweight 433 is screwed to the center rod 43, and the center rod 43 is provided with a communication hole through which the optical fiber passes through the center rod 43.
As shown in FIG. 11, the connection stand 432 connects 12 sets of first airbags 45 arranged radially.
The 12 sets of first airbags 45 are connected to the housing 41 via the connecting base 43 at one end.
2, and the other end is connected to the housing 41.
As shown in FIG. 12, three
Three sets of drive gears 46 are provided, and the three sets of drive gears 46 are arranged at 120° to each other, thereby ensuring the stability of the weight of the float stabilizer 4, and the transmission ring 42 has two sets of drive gears 46. A toothed disc 421 is provided which meshes with.
As shown in FIGS. 13 and 15, on the side wall of the housing 41, there is a
12 sets of corresponding branch pipes 47 are provided, and each set of branch pipes 47 is connected to the first air bag 45 provided on the opposite side via a tube, and an annular groove 4 is formed in the outer wall of the transmission ring 42.
22 are provided in the upper and lower parts of the branch pipe 47, respectively, and a groove 1 that enters the corresponding annular groove 422 is provided.
A set of second airbags 471 is provided.
As shown in FIGS. 13 and 14, countersinks 423 are provided in the transmission ring 42 located at the inner bottom of the annular groove 422, and correspond to each second airbag 471 on a one-to-one basis. A counterweight slider 424 is slidably provided, and the counterweight slider 4
One side of the counterweight slider 424 is connected to the inner bottom of the countersink 423 via two sets of springs 425, and an arcuate sheet 426 is provided on the other side of the counterweight slider 424.
A pair of guide grooves 427 are respectively provided on the transmission rings 42 on both sides of the drive ring 3, which are slidably connected to the guide rods of the arcuate seat 426.
As shown in FIG. 13, the annular groove 4 between the arcuate seat 426 and the second airbag 471
An elastic ring 428 is provided within the second airbag 471, and the elastic ring 428 is slidably connected to the end surface of the second airbag 471.
As shown in FIGS. 10 and 11, the housing 41 is provided with a cover 412 that covers each tube, and solar panels or batteries are laid on the surface of the cover 412 in a staggered manner at intervals. A commercially available lithium battery covered with a heat insulating plate is used, and the housing 41 is provided with a drive motor that butts against the shaft of the drive gear 46, and the drive motor is connected to a solar panel or battery via a relay. The relay and drive motor are commercially available products, or commercially available rotary motors and commercially available relays with external shapes adjusted to suit installation on this device.
Both the housing 41 and the transmission ring 42 may be made of rigid foam, thereby ensuring the buoyancy of the float stabilizer 4 on the water surface.
The operating principle of the float stabilizer 4 is as follows.
The bottom of the condenser is engaged with and fixed to the connection base 432, and the other end of the optical fiber to which the condenser is connected is passed through the communication hole provided in the center rod 43, placed into the metal casing, and placed into the sludge. The metal casing is then removed and the optical fibers are placed radially into the sludge.
The drive motor is started to rotate the drive gear 46, and the drive gear 46 and the two sets of transmission rings 42 are connected to each other.
The two sets of transmission rings 42 are rotated clockwise and counterclockwise by the action of the transmission by the toothed disc 421, respectively, to maintain a stable dynamic balance.
When large waves occur on the water surface, the condenser is always perpendicular to the center of gravity due to the action of the center rod 43, and at this time, the related members of the housing 41 are the ball 431 of the center rod 43 and the socket of the mounting plate 44. 441, and during the swing, the housing 41 and the connection base 43
The first airbag 45 between the two is pushed or pulled.
In the dynamically balanced cavity formed by the second airbag 471 and the first airbag 45 of the diverter pipe 47, for example, when the first airbag 45 is pushed, The second airbag 471, which is provided at an angle of 180°, extends,
In the extended state, the second airbag 471 pushes the elastic ring 428 toward the counterweight slider 424.
Therefore, due to the above action, when the center of gravity of the transmission ring 42 shifts, that is, when the housing 41 tilts downward to the left as shown in FIG.
4 is closer to the center of gravity of the transmission ring 42, and the counterweight slider 424 on the right side is further away from the center of gravity of the transmission ring 42. At this time, when the transmission ring 42 rotates, the risk of the float stabilizer 4 overturning is greatly reduced. Ru.

Example 6
This example is the same as Example 5 except that, as shown in FIG. 6, the water is black-smelling water, and in the case of black-smelling water, the optical fiber is arranged in the dark-smelling water in a shape that imitates aquatic plants. .

Example 7
This example is similar to Example 3 in the following points. As shown in FIGS. 7 and 16, the light source module includes a float light source device 2, the float light source device 2 includes a light source unit 3, and a float stabilizer 4, and the light source unit 3 is specifically a condenser. be.
As shown in FIG. 17, the float stabilizer 4 includes a housing 41 and two sets of transmission rings 4.
2 and a center rod 43, the housing 41 is hollow inside, and is provided with a center cylindrical body 411 in the center for swinging the center rod 43. The two sets of transmission rings 42 provided on the inner top surface and the inner bottom surface each have a central cylinder body 411.
It is rotatably mounted.
As shown in FIG. 22, a mounting plate 44 is provided at the center of the central cylindrical body 411, and a socket 441 is rotatably fitted to a ball 431 provided on the center rod 43 at the center of the mounting plate 44. will be provided.
As shown in FIG. 18, a connection stand 432 connected to the light source unit 3 is provided at the upper end of the center rod 43, and a counterweight 433 is screwed to the center rod 43 at the lower end of the center rod 43.
is provided, and the counterweight 433 may be mounted on a plurality of center rods 43 according to actual usage needs, and the counterweight 433 is screwed to the center rod 43, and an optical fiber is passed through the center rod 43. A communicating hole is provided for the purpose.
As shown in FIGS. 17 and 18, the connection base 432 is connected to the housing 41 via 12 sets of first airbags 45 arranged radially, and one end of each of the 12 sets of first airbags 45 is connected to the connection base. 432, and the other end is connected to the housing 41.
As shown in FIG. 18, one
Two sets of drive gears 46 are provided and correspond one-to-one to the first airbag 45, the transmission ring 42 is provided with a toothed disc 421 that meshes with the drive gear 46, and the side wall of the housing 41 includes: Twelve pairs of stabilizers 48 are provided that correspond to the first airbags 45 on a one-to-one basis.
As shown in FIGS. 19 and 20, the stabilizer 48 includes a rotating rod 481, a rotating bush 482, and a third airbag 484, and the rotating bush 482 is connected to a fixed block 483 provided on the side wall of the housing 41. Two sets of restriction ribs are provided on the side wall of the rotation rod 481, and the two sets of restriction ribs are provided at an angle of 180°.
is slidably engaged with the rotary bush 482, and the inner wall of the rotary bush 482 is provided with a restriction groove that fits with the restriction rib.
As shown in FIG. 19, the lower end of the third airbag 484 is rotatably connected to the upper end of a rotating rod 481, and two sets of discs 485 are installed at the lower end of the rotating rod 481, and the third airbag 484 is The upper end of the airbag 484 is connected to the corresponding first airbag 45 via a tube.
As shown in FIGS. 18, 19, and 21, the output shaft of the drive gear 46 passes through the housing 41 and is connected to the first bevel gear 486. A second bevel gear 487 is provided which meshes with each other for transmission.
As shown in FIGS. 18 and 19, there is no rotary bush 4 in any of the three sets of fixed blocks 483.
A ring motor connected to 82 is provided, and three sets of fixed blocks 483 are connected to each other by 12
There are three sets of fixed blocks 483 installed at 0° intervals, a solar panel or battery is installed in the housing 41, a ring motor is connected to the solar panel or battery via a relay, and the battery has a heat insulating plate on its surface. A covered commercially available lithium battery is used, the ring motor and the relay are commercially available products, or the external shapes of commercially available motors and commercially available relays are adjusted to suit installation in this device, and the housing 41 and the transmission ring 42 are The float stabilizer 4 may also be made of rigid foam, which ensures the buoyancy of the float stabilizer 4 on the water surface.
The operating principle of the float stabilizer 4 is as follows.
The bottom of the condenser is engaged with and fixed to the connection base 432, and the other end of the optical fiber to which the condenser is connected is passed through the communication hole provided in the center rod 43, placed into the metal casing, and placed into the sludge. The metal casing is then removed and the optical fibers are placed radially into the sludge.
The drive motor is started to rotate the drive gear 46, and the drive gear 46 and the two sets of transmission rings 42 are connected to each other.
Due to the transmission action of the toothed disc 421, the two sets of transmission rings 42 are rotated clockwise and counterclockwise, respectively, to maintain stable balance.
When large waves occur on the water surface, the action of the central rod 43 keeps the concentrator always facing the direction of gravity, i.e. vertically, and at this time, the associated parts of the housing 41 are connected to the central rod 43.
The first air bag 45 between the housing 41 and the connection base 432 is pushed or pulled during the swing.
For example, when the first airbag 45 is pushed in the dynamically balanced cavity formed by the third airbag 484 and the first airbag 45 of the stabilizer 48,
The corresponding third airbag 484 extends downward, and in the extended state, the third airbag 484
pushes the rotating rod 481 toward the water surface.
Therefore, due to the above action, the raised stabilizer 48 maintains contact between the disc 485 and the water, that is, as shown in FIG. 17, when the housing 41 tilts downward to the left,
The first airbag 484 on the left side is pulled, and the third airbag 484 and the first airbag 45
In the dynamically balanced cavity formed by the third airbag 484
is contracted upward, the disc 485 approaches the housing 41, and the first airbag 484 on the right side
is pushed, the third airbag 484 at the corresponding position extends downward, and the disc 485 separates from the housing 41. At this time, when the transmission ring 42 rotates, the drive gear 46 and the first bevel gear 486 , the rotation rod 481 and the rotation bush 482 of each stabilizer 48 rotate due to the transmission operation by the second bevel gear 487, and the two sets of discs 485 maintain stable dynamic balance in the water, so that the float The risk of the stabilizer 4 overturning is greatly reduced, and the problem of the disc 485 of the stabilizer 48 touching the bottom or leaving the water surface due to too small water depth is effectively avoided.

Example 8
This example is the same as Example 7, except that the water is black-smelling water, and in the case of black-smelling water, the optical fiber is placed in the dark-smelling water in a shape that imitates aquatic plants.

Experimental Examples Examples 1 and 2, Examples 3 and 4, Examples 5 and 6, and Examples 7 and 8 of the present invention are solutions for dealing with black-smelling water and sludge water, so one of them We will conduct experiments to examine the treatment effects of the in-situ photocatalytic system.
Examples 2, 4, 6, and 8 were conducted using dark-smelling water in this city as the test subject for Examples 2, 4, 6, and 8.
were treated as experimental group 1, experimental group 2, experimental group 3, and experimental group 4, respectively, and black-smelling water was treated for 10 d. Considering that the natural environment changes frequently, in this experiment, natural light was irradiated within 10 d. The light was irradiated for 14 hours a day under simulated conditions, and the intensity of the light irradiation from the self-luminous light source corresponded to the average light irradiation intensity and light irradiation time of the simulated natural light irradiation, and the following study was conducted.
Study 1: Measuring the influence of self-luminous light sources and concentrators on the effectiveness of the in-situ photocatalytic system Experimental groups 1 and 2 were used as comparison experiments, and control group 1 did not use the in-situ photocatalytic system.
One set was installed, and the treatment effect on black-smelling water was measured after 10 days, and the results are shown in Table 1 below.
Table 1 Comparison table of treatment parameters for black odor water

As can be seen from the results in Table 1 above, when comparing the experiments of experimental groups 1 and 2 and control group 1,
When black odor water is treated with the in-situ photocatalytic system of the present invention, the usage effect is good;
It can effectively solve the problem of sunlight not directly hitting the black-smelling water, and in-situ pollution remediation can be done in an environment-friendly manner with clean energy.
On the other hand, the results of comparing the experiments of experimental groups 1 and 2 revealed that when using the optical fiber coated with nitrogen-doped _TiO2 , the processing effects of the self-luminous light source and the condenser are almost the same, and the When the light is sufficient, the treatment effect of in-situ photocatalysis is excellent even when using a condenser, and the energy is clean and has the advantages of being environmentally friendly.
Study 2: Measuring the effects of near-field light source devices and float light source devices on the effectiveness of in-situ photocatalyst systems Experimental groups 2, 3, and 4 were used as comparison experiments, and control group 2, which used a light concentrator mounted on a float plate, was used as a comparison experiment. One set was installed, and the treatment effect on black-smelling water was measured after 10 days, and the water surface was waved for 8 hours within the light irradiation time of one day.The results are shown in Table 2 below.
Table 2 Comparison table of treatment parameters for black odor water

As can be seen from the results in Table 2 above, as a result of comparing the experiments of experimental groups 2, 3, and 4, in the present invention, when the float stabilizer 4 is equipped with a condenser, the effect of using the condenser on the ground are almost the same.
On the other hand, as a result of comparing the experiments of Experimental Groups 3 and 4 and Control Group 2, it was found that the wave motion on the water surface affects the light collection efficiency of the light collector to a certain extent, so the float stabilizer 4 of the present invention can solve this problem. This can be effectively solved and the risk of the float stabilizer 4 overturning can be significantly reduced.
[Explanation of symbols]

1 - Nearby light source device 2 - Float light source device 3 - Light source unit 4 - Float stabilizer 41 - Housing 411 - Center cylinder 412 - Cover 42 - Transmission ring 421 - Tooth disc 422 - Annular groove 423 - Countersink 424 - Counterweight Slider 425 - Spring 426 - Arc-shaped sheet 427 - Guide groove 428 - Elastic ring 43 - Center rod 431 - Ball 432 - Connection stand 433 - Counter weight 44 - Placement plate 441 - Socket 45 - First airbag 46 - Drive gear 47 - Diversion pipe 471 - Second airbag 48 - Stabilizer 481 - Rotating rod 482 - Rotating bush 483 - Fixed block 484 - Third airbag 485 - Disc 486 - First bevel gear 487 - Second bevel gear

Claims (7)

including a light source module for providing a light source and an optical fiber for supporting a catalyst;
One end of the optical fiber is butted against the light exit of the light source module, the other end of the optical fiber is submerged in water,
The catalyst is one of TiO ₂ and BiO ₂ , and the TiO ₂ is nitrogen-doped TiO ₂ .
The catalyst is supported on the optical fiber by one of immersion calcination and gel coating.
An in-situ photocatalytic system characterized by: The system according to claim 1, wherein the water is black-smelling water or sludge water. The optical fiber is
1) In the case of the black-smelling water, an optical fiber is arranged in the black-smelling water in a shape imitating aquatic plants;
1) In the case of the sludge water, two forms are adopted: a form in which optical fibers are dispersed in the sludge in the form of a dot matrix;
3. The system of claim 2. The light source module uses a near-field light source device (1) or a float light source device (2), the float light source device (2) includes a light source unit (3) and a float stabilizer (4), and the near-field light source device (1) includes a light source unit (3) and a float stabilizer (4). ), the light source unit (3) is one of a self-luminous light source or a concentrator. The float stabilizer (4) includes a housing (41) and two sets of transmission rings (42).
and a center rod (43),
The housing (41) is hollow inside, and is provided with a central cylindrical body (411) in the center of which the central rod (43) swings, and the two sets of transmission rings (42) are connected to the housing (41), respectively. 41), and two sets of transmission rings (42) are rotatably mounted on the central cylinder (411),
A mounting plate (44) is provided at the center of the center cylinder (411), and is rotatable at the center of the mounting plate (44) around a ball (431) provided on the center rod (43). A socket (441) is provided to be fitted into the
A connection stand (432) connected to the light source unit (3) is provided at one end of the center rod (43), and a counterweight screwed to the center rod (43) is provided at the other end of the center rod (43). (
433), and the center rod (43) is provided with a communication hole through which the optical fiber passes through the center rod (43),
The connection stand (432) is connected to the housing (41) via a plurality of sets of first airbags (45) arranged radially, and the plurality of sets of first airbags (45) are all connected at one end. connected to the stand (432), the other end connected to the housing (41),
At least one set of drive gears (46) is rotatably provided on the inner wall of the housing (41) located between the two sets of transmission rings (42), and the drive gears (46) are rotatably provided in the transmission ring (42).
5. System according to claim 4, characterized in that a toothed disc (421) is provided which meshes with the toothed disc (46). A plurality of sets of branch pipes (47) corresponding to the first airbag (45) on a one-to-one basis are provided on the side wall of the housing (41), and the branch pipes (47) are connected to the opposite side through a tube. connected to a first airbag (45) provided;
An annular groove (422) is provided on the side wall of the transmission ring (42), and a pair of second airbags (471) are provided in the upper and lower parts of the diverter pipe (47), respectively, entering the corresponding annular groove (422).
) is provided,
Each second airbag (
A countersink (423) corresponding to the countersink (471) on a one-to-one basis is provided, a counterweight slider (424) is slidably provided in the countersink (423), and one side of the counterweight slider (424) is provided. is connected to the inner bottom of the countersink (423) via a spring (425), and an arcuate sheet (426) is provided on the other side of the counterweight slider (424), and both sides of the countersink (423) An arc-shaped seat (42) is attached to the transmission ring (42) of
a set of guide grooves (427) slidably connected to the guide rods of 6);
An annular groove (422) between the arcuate seat (426) and the second airbag (471)
An elastic ring (428) is provided within the second airbag (428), and the elastic ring (428) is connected to the second airbag (428).
71) is slidably connected to the end face of the
The housing (41) is provided with a cover (412) that covers each tube, and at least one of a solar panel or a battery is laid on the surface of the cover (412),
Further, the housing (41) is provided with a drive motor that butts against the shaft of the drive gear (46), and the drive motor is connected to a solar panel or a battery via a relay. The system according to item 5. A plurality of sets of stabilizers (48) are provided on the side wall of the housing (41) in one-to-one correspondence with the first airbag (45),
The stabilizer (48) includes a rotating rod (481), a rotating bush (482), and a third airbag (484), and the rotating bush (482) is provided on a side wall of the housing (41). The rotary rod (483) is rotatably connected to the fixed block (483)
1), the pivot rod (481) is slidably engaged with the pivot bush (482), and the inner wall of the pivot bush (482) is provided with at least one set of limitation ribs; A restriction groove is provided that fits with the
One end of the third airbag (484) is rotatably connected to one end of a rotating rod (481), and at least one set of discs (485) is provided at the other end of the rotating rod (481). and the other end of the third airbag (484) is connected to the corresponding first airbag (45) via a tube,
A plurality of sets of the drive gears (46) are provided and correspond to the first airbag (45) on a one-to-one basis, and the output shaft of the drive gear (46) passes through the housing (41). 1 bevel gear (
486), a second bevel gear (487) that meshes with the first bevel gear (486) and transmits transmission is disposed on the rotary bush (482),
At least one set of the fixed blocks (483) is provided with a ring motor connected to the rotary bush (482), at least one of a solar panel or a battery is installed in the housing (41), and the System according to claim 5, characterized in that the ring motor is connected to a solar panel or a battery via a relay.