JP4195204B2 - Water treatment equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention is suitable for improving the water quality of various water areas such as water reservoirs, pools, aquariums, ponds, lakes, harbors, underground waterways, etc.WaterThe present invention relates to a processing apparatus.
[0002]
[Prior art and problems to be solved by the invention]
  Maintaining good water quality such as ponds, lakes, and groundwater veins is a very important issue for us from the viewpoint of nature conservation and various other aspects. In particular, in recent years, the mixing of environmental hormones and carcinogenic substances in natural water and the growth of algae have become major problems. However, when we look at the actual situation, it cannot be said that improvement of water quality in the natural world is being promoted appropriately and sufficiently. In the past, for example, when water pollution of ponds and lakes progressed and algae grew in large quantities, it was actually the case that algae were removed by human sea tactics afterwards, and water quality improvement was routine. However, there are few active measures such as continuous implementation and prevention of water pollution. In the past, pumping up contaminated water using a large pump and then filtering it with a filtering device, but such facilities in the past are very large, There is a problem in that it is expensive and the cost required for maintenance and operation is high. In addition, the location where water is pumped up by the pump is almost constant, and it has been difficult to efficiently improve the water quality of ponds and lakes with a large amount of water.
[0003]
  On the other hand, not only in the natural world, but also in artificially stored water such as pool water in schools and sports facilities, or water in aquariums and domestic aquariums, it is required to maintain the water quality at a certain level. Often done. Conventionally, as means for maintaining the quality of water in a predetermined state, for example, a means has been adopted in which water is pumped using a pump and then filtered by a filtering device, as described above. Therefore, even in this case, there are cases where the cost of the apparatus becomes high or the efficiency of water quality improvement is poor.
[0004]
  The present invention has been conceived under such circumstances, and an object thereof is to enable water quality improvement processing to be performed efficiently and appropriately at low cost.
[0005]
DISCLOSURE OF THE INVENTION
  In order to solve the above problems, the present invention takes the following technical means.
[0006]
[0007]
[0008]
[0009]
[0010]
[0011]
[0012]
[0013]
[0014]
[0015]
[0016]
[0017]
[0018]
[0019]
[0020]
  The water treatment apparatus provided by the present invention is a flow that can float on water.GA rotating part that is positioned below the float, is supported rotatably around the vertical axis with respect to the float, and is rotatableMaterial, andSupported by the rotating member,UpBelow the floatA water inlet located in the water, a pump, a water quality improvement unit configured to be able to improve the water quality by passing water through the inside, and a water outlet that faces the direction opposite to the water inlet below the float At the same time, by the operation of the pump, the water absorbed from the water inlet is discharged from the water outlet through the water quality improvement unit.Pump unitGOf the above pump unitthe aboveWater absorption from the water inlet and aboveAbove pump unitPropulsive force is generated by the action of at least one of the water discharged from the spout, and the direction of the propulsive force can be changed by rotationally driving the rotating member with respect to the float. It is a feature.
[0021]
  According to the water treatment apparatus having such a configuration, the water treatment apparatus can be floated in the water quality improvement target water area using the float. When the pump unit is operated in such a state, water quality improvement processing using the water quality improvement unit can be performed.The pump unit also serves as a propulsion device, and the direction of the propulsive force can be easily changed, which is convenient for moving the water treatment device. Further, since it is not necessary to provide a propulsion device different from the pump unit in the water treatment device, the configuration of the device can be simplified.
[0024]
  In another preferred embodiment of the present invention, at least one of a rechargeable battery and a power generation means such as a solar battery is mounted as a power supply source for the pump unit.
[0025]
  According to such a configuration, when the water treatment apparatus is floated in a desired water area, it is not necessary to supply power to the water treatment apparatus from the land via a cable, which is convenient.
[0026]
  In another preferred embodiment of the present invention, the operation of the pump unit can be turned on / off and the direction of the propulsive force can be changed by remote control.
[0027]
  According to such a configuration, an operation for moving the water treatment device is facilitated.
[0028]
  In another preferred embodiment of the present invention, a water quality inspection device and communication means for wirelessly outputting data of a result of the water quality inspection performed by the water quality inspection device are provided.
[0029]
  According to such a configuration, it is possible to execute a water quality test in addition to the water quality improvement process and to know the result of the water quality test at a place away from the water treatment device.
[0030]
  In another preferred embodiment of the present invention, a position measuring unit capable of measuring its own position is provided, and position data measured by the position measuring unit is wirelessly output by the communication unit. It is configured as follows.
[0031]
  According to such a configuration, the location of the water treatment apparatus can be monitored at a place away from the water treatment apparatus, and the water treatment apparatus can be accurately arranged at a desired position. In addition, when a water quality test is performed, it is possible to detect which water area the result of the water quality test is.
[0032]
  In another preferred embodiment of the present invention, when the communication means receives a predetermined command signal for the destination, the pump unit is operated so as to move the water treatment device toward the destination. And a control means for controlling the direction of the propulsive force.
[0033]
  According to such a structure, it is realizable to move a water treatment apparatus to a desired designated location by automatic control.
[0034]
  In another preferred embodiment of the present invention, there is provided inspection means capable of inspecting certain items relating to the water treatment apparatus, and data of the result of inspection performed by the inspection means is wirelessly transmitted by the communication means. Output is possible.
[0035]
  According to such a configuration, when a predetermined abnormality occurs in the water treatment apparatus, this can be known at a place away from the water treatment apparatus.
[0036]
  In another preferred embodiment of the present invention, the pump unit can suck external air and discharge the sucked air into water.
[0037]
  According to such a structure, aeration (aeration) to water can also be performed efficiently. Since this aeration is performed by using the operation of the pump unit, it is not necessary to separately incorporate a special device for performing aeration, and the device structure can be suppressed as much as possible.
[0038]
  In another preferred embodiment of the present invention, the pump unit isthe aboveWater intake andthe aboveThe height of the spout is different from each other.
[0039]
  According to such a configuration, the depth of the portion where the water is sucked into the water inlet is different from the depth of the portion where the water whose quality has been improved is discharged into the water, while stirring the water. It becomes possible to improve water quality efficiently.
[0040]
  In another preferred embodiment of the present invention, the height of at least one of the water inlet and the water outlet can be changed.
[0041]
  According to such a configuration, by adjusting the height of at least one of the water inlet and the water outlet, for example, the distance between the water inlet and the water outlet is set to a dimension corresponding to the water depth of the water quality improvement target water area. It becomes possible to set.
[0042]
  In another preferred embodiment of the present invention, there is provided control means for performing control to reverse the pump of the pump unit when a predetermined condition is satisfied.
[0043]
  According to such a structure, what is called a pump unit can be backwashed by reverse rotation of the pump. That is, for example, when foreign matter is clogged in the piping of the pump unit, an effect of eliminating the clogging by reversing the direction of the water flow in the piping can be expected.
[0044]
  In another preferred embodiment of the present invention, the water quality improvement unit has a cylindrical casing and a plurality of magnets accommodated in the casing, and a space between the plurality of magnets is provided. The flow channel is formed with a magnetic field that generates magnetic lines of force in a direction intersecting the water flow.
[0045]
  It is known that the water quality improvement unit having the above structure exhibits an action of decomposing trihalomethane, which is one of carcinogenic substances. Further, according to the water quality improvement unit having the above configuration, when water containing impurities passes through the magnetic field, an electromotive force is generated according to Faraday's law which refers to the interaction, and the water can be made weakly alkaline by the action. Water quality improvement effect is also obtained.
[0046]
  In another preferred embodiment of the present invention, the water quality improvement unit includes a unit in which an electrode for electrolysis is provided in a casing, a unit in which ultrasonic generating means is provided in the casing, and a casing. Is one of the units provided with the far infrared irradiation means. In the present invention, such a water quality improvement unit can also be applied.
[0047]
[0048]
[0049]
  Other features and advantages of the present invention will become more apparent from the following description of embodiments of the invention.
[0050]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, a preferred embodiment of the present invention will be specifically described with reference to the drawings.
[0051]
  1 to 5 show an embodiment of the present invention. As shown well in FIG. 1, the water treatment apparatus A of this embodiment includes a float 1, a solar cell panel 2, a pump unit 3, a water quality improvement unit 4, a water quality inspection apparatus 6, and apparatus equipment described later. It is comprised.
[0052]
  The float 1 is made of, for example, a synthetic resin and is formed in a hollow drum shape inside. This float 1 can exhibit the buoyancy which can support each part of the water treatment apparatus A and can float on water. The solar cell panel 2 is for obtaining electric power necessary for driving each part of the water treatment apparatus A, and is supported on the upper part of the float 1 via a support member 20. As clearly shown in FIG. 2, the solar cell panel 2 can swing in the direction of the arrow Na around the shaft 21 on the upper side of the support member 20, and also in the horizontal direction of the arrow Nb around the shaft 22. Can be rotated, and its posture and orientation can be adjusted so that sunlight can be received efficiently. Preferably, the water treatment apparatus A is provided with a follow-up device for always directing the solar cell panel 2 to the sun. As an example of the follow-up device, an optical sensor for determining the direction of the sun and an operation mechanism for operating the solar cell panel 2 so that the solar cell panel 2 is directed in the direction of the sun determined using the optical sensor. It is possible to apply a device that combines the above. Instead of this, it is possible to determine the approximate direction in which the sun exists by using a magnetic compass and control the solar cell panel 2 so that it is directed in that direction. Of course, the solar cell panel 2 can also be fixed in an upward horizontal posture.
[0053]
  The pump unit 3 includes a pump 30, a water absorption element 31, a telescopic tube 32, a water discharge element 33, and a pump driving motor M1. Among these components of the pump unit 3, components other than the motor M1 are provided below the float 1 so as to be located in the water when the float 1 is floated on the water.
[0054]
  As the pump 30, for example, a vane pump is applied and supported by the stay 35a. The stay 35 a is attached to the rotating plate 50 and can rotate in the arrow Nd direction around the vertical axis. More specifically, the rotating plate 50 is rotatably attached to the bottom of the float 1. When the drive shaft of the motor M2 attached to the support member 51 in the float 1 rotates, the pair of gears 52a and 52b. The shaft 53 that is drivingly connected to the motor M <b> 2 via the rotation rotates, and the rotation plate 50 rotates in the above direction along with the shaft 53. The portion where the rotating plate 50 and the bottom of the float 1 are in sliding contact with each other has a structure that can prevent water from entering the float 1. In the present embodiment, since the stay 35a can rotate around the vertical axis by driving the motor M2, the entire pump unit 3 can also rotate in the direction of the arrow Nd along with the stay 35a. This rotation operation is useful for changing the traveling direction of the water treatment apparatus A as will be described later.
[0055]
  The water absorption element 31 is connected to the suction port of the pump 30. The water absorption element 31 has, for example, a hollow, flat and substantially drum shape, and a plurality of slit-shaped water intake ports 31a are provided in the front portion facing the left in FIG. 2 and the vicinity thereof. The water discharge element 33 is connected to the discharge port of the pump 30 via the water quality improvement unit 4 and the telescopic pipe 32, and has a height lower than that of the water absorption element 31. A plurality of slit-shaped water discharge ports 33a facing in the direction opposite to the water suction port 31a are provided on the rear surface portion of the water discharge element 33 facing right in FIG. 2 and in the vicinity thereof. As described above, since both the water inlet 31a and the water outlet 33a are oriented substantially in the horizontal direction and opposite to each other, the pump unit 3 has an action of sucking water into the water inlet 31a and The function of propelling the water treatment device A in the direction of the arrow Nc on the front surface of the water suction port 31a by the action of discharging water from the water discharge port 33a also exhibits, and corresponds to an example of the propulsion device referred to in the present invention. As described above, the pump unit 3 can be rotated in the direction of the arrow Nd. When the pump unit 3 is rotated in the same direction, the directions of the water inlet 31a and the water outlet 33a are changed. The moving direction of can be changed.
[0056]
  The telescopic tube 32 has, for example, a structure in which a plurality of tube bodies are slidably fitted, or is formed in a bellows shape so that the telescopic tube 32 is telescopic in the axial direction. By extending / contracting the expansion / contraction tube 32, the height of the water discharge element 33 can be adjusted within a certain range as shown by an imaginary line in FIG.
[0057]
  The motor M <b> 1 is attached on the rotating plate 50 in the float 1. The drive shaft of the motor M1 and the rotor 30a of the pump 30 are connected to each other through a connecting rod 34 inserted into a tubular body 55 penetrating a part of the water absorption element 31 and the rotary plate 50, and the rotor 30a. Is rotated by the driving force of the motor M1. The pipe body 55 is for guiding the air in the float 1 into the pump 30, and its upper end opening is located in the float 1, while its lower end opening is located in the vicinity of the suction port of the pump 30. ing. One or a plurality of air inlets 10 for introducing air into the float 1 are provided in a portion above the draft line of the float 1.
[0058]
  As shown well in FIG. 3, the water quality improvement unit 4 includes a short tubular casing 40 and a plurality of magnets 41 accommodated in the casing 40. The plurality of magnets 41 are permanent magnets formed by, for example, magnetizing a rod-shaped metal, and are supported by an appropriate member (not shown). A plurality of water channels 42 extending in the axial length direction of the casing 40 are formed between the plurality of magnets 41. The plurality of magnets 41 are arranged so that different magnetic poles face each other, and a magnetic field that generates magnetic force lines in a direction perpendicular to the direction in which water flows in the flow channel 42 is formed in the flow channel 42. ing. The water quality improvement unit 4 is connected to the discharge side of the pump 30 so that the water discharged from the pump 30 flows in the flowing water channel 42. However, the present invention is not limited to this, and the water quality improvement unit 4 may be provided on the suction side of the pump 30.
[0059]
  The water quality inspection device 6 is configured such that when the water treatment device A is floated on water, the water is collected or brought into contact with the water to perform a desired water quality inspection. The specific content of the water quality inspection performed by the water quality inspection device 6 is not particularly limited, and may be, for example, detection of the concentration of a desired component or substance such as trihalomethane or chlorine, or simple pH value measurement. . The water quality inspection device 6 is attached to the bottom of the float 1, for example, but instead, it may be configured to be incorporated in the piping of the pump unit 3. Further, when it is desired to perform a water quality test at a location where the water depth is deep, the water quality test apparatus 6 may be supported by a stay 35 b provided so as to protrude downward from the pump 30.
[0060]
  In the float 1, a control unit 70, a rechargeable battery 71, a voltage measuring device 72, a wireless communication unit 73, and a position measuring unit 74 shown in FIG. 4 are also provided.
[0061]
  The wireless communication unit 73 is capable of wireless transmission / reception via the antenna ANT1. More specifically, as shown in FIG. 5, the wireless communication unit 73 is capable of bidirectional wireless communication between a predetermined monitoring device 90 and a base station 91 connected via a telephone line. Yes. As the monitoring device 90, a computer capable of online connection to a communication network such as the Internet is used.
[0062]
  The control unit 70 includes, for example, a CPU and a memory such as a RAM and a ROM connected to the CPU, and is based on a program stored in advance in the memory and a control command transmitted from the monitoring device 90 to the wireless communication unit 73. The control of each part of the water treatment apparatus A and signal processing are executed. The water quality inspection device 6 is configured to be activated under the control of the control unit 70 and to input the data to the control unit 70 when a result of the water quality inspection is obtained as a result of the activation. This data can be output wirelessly via the wireless communication unit 73. The rechargeable battery 71 is configured to be able to store electric power generated by the solar battery panel 2 and supply necessary electric power to each part of the water treatment apparatus A.
[0063]
  The water treatment apparatus A is configured to detect a voltage drop of the rechargeable battery 71 exceeding a certain value or a pressure abnormality in the pump unit 3. More specifically, the voltage measuring device 72 is configured to measure the voltage of the rechargeable battery 71 and input the data to the control unit 70, and the control unit 70 reduces the measured voltage value to a certain value or less. When this happens, it is configured to wirelessly output data to that effect via the wireless communication unit 73. As shown in FIG. 2, the pump unit 3 is provided with a pressure sensor 75. When the internal pressure becomes a certain level or more due to, for example, clogging in the pump unit 3, the control unit 70 is wireless. It is configured to wirelessly output data to that effect via the communication unit 73. Various abnormal situations that occur when using the water treatment apparatus A can be considered in addition to insufficient voltage of the rechargeable battery 71 and clogging in the pipe line of the pump unit 3. Therefore, in this invention, it can comprise so that the abnormal condition other than the above can also be detected via the control part 70. FIG.
[0064]
  When the pressure measured by the pressure sensor 75 exceeds a certain level, the control unit 70 performs wireless output to that effect using the wireless communication unit 73, and simultaneously controls the motor M1 for a certain period of time or the measured pressure. It is configured to perform reverse rotation control until the voltage drops. This reverse rotation of the motor M1 reverses the direction of water flow in the pump unit 3, thereby helping to promote the removal of foreign matter that has been clogged. When the measured value decreases due to the reverse rotation of the motor M1, the control unit 70 performs control to drive the motor M1 as usual after that.
[0065]
  The position measuring unit 74 is configured to measure the position of the water treatment apparatus A and input the data to the control unit 70. The position measurement by the position measurement unit 74 is performed using, for example, GPS (Global Positioning System). The principle of position measurement executed by the position measuring unit 74 is the same as that of a car navigation system, in which radio waves (time signals) transmitted from a predetermined plurality of artificial satellites are received by an antenna ANT2, and those This is done by calculating the time lag of radio waves. Of course, in the present invention, the position of the water treatment apparatus A may be measured by using a position measurement system different from the GPS.
[0066]
  The control unit 70 is configured to control the water treatment apparatus A to move to a predetermined location by controlling the driving of the motors M1 and M2 via the drivers 75a and 75b. More specifically, in the water treatment apparatus A, as described above, the water treatment apparatus A can be moved when the pump unit 3 sucks and discharges water. Control of the movement start and stop thereof is performed by the control unit 70 controlling the motor M1. Moreover, since the moving direction of the water treatment apparatus A can be changed by changing the direction of the water intake port 31a and the water discharge port 33a of the pump unit 3, the control unit 70 controls the movement direction of the water treatment apparatus A. This is done by controlling M2. The control unit 70 refers to the position data of the water treatment device A detected by the position measurement unit 74, thereby performing movement control so as to guide the water treatment device A to a predetermined position designated by the monitoring device 90. It is possible.
[0067]
  Next, an example of the water treatment method performed using the water treatment apparatus A having the above configuration will be described.
[0068]
  First, for example, when improving the water quality of a reservoir, the buoyancy of the float 1 is used to float the water treatment device A at a predetermined location in the reservoir. When the pump 30 is operated in such a state, the water in the reservoir is supplied into the water quality improvement unit 4 after being sucked into the pump 30 from each water inlet 31a, and the water quality is modified. The water whose quality has been modified is returned to the water from each outlet 33a. The water quality improvement unit 4 has the structure described with reference to FIG. 3, and according to the water quality improvement unit 4 having such a structure, it is possible to decompose trihalomethane, which is a carcinogenic substance, as already described. Are known. Moreover, according to this water quality improvement unit 4, when the water containing an impurity passes through the flowing water channel 42, a change occurs in the magnetic field of the flowing water channel 42 to generate an electromotive force, and the water is weakly alkaline by electrolysis. It can also be. Furthermore, when impurities such as rust are contained in the water, the impurities obtain energy by the action of the lines of magnetic force and have properties such as charging, and the impurities adhere to each other and grow large. Alternatively, impurities dissolved in water gain energy and crystallize into particles. Thereby, the transparency of water is improved.
[0069]
  When the pump 30 is driven, as described above, a propulsive force is generated in the water treatment apparatus A. Therefore, if no means is taken, the water treatment apparatus A will be separated from the original setting location. For this reason, as a means for keeping the water treatment apparatus A in the vicinity of the initial setting place, for example, the control unit 70 controls the motor M2 to control the movement direction of the water treatment apparatus A, and the water treatment apparatus A Are circulated in an appropriate constant locus such as a circle or a rectangle in a certain area. In this way, it is possible to continue the water quality improvement process at and around the original setting location.
[0070]
  When the pump 30 is driven, the air in the float 1 is sucked into the pump 30 through the pipe body 55 due to the negative suction pressure. The sucked air is discharged into the water from each water outlet 33a in a state of being mixed with the water that has passed through the water quality improvement unit 4. Therefore, water quality improvement by aeration is achieved at the same time. Since each water outlet 33a is set at a position lower than each water inlet 31a, it is suitable for feeding treated water and air into a deep part. In addition, since water close to the water surface can be sucked into the pump unit 3 and then discharged to a deep water location, water agitation is improved, which also promotes water quality improvement.
[0071]
  Since the height of the water discharge element 33 and each water discharge port 33a can be adjusted by the expansion and contraction action of the expansion and contraction tube 32, for example, regardless of whether the water depth is shallow or deep, each water discharge port 33a has a height close to the bottom of the water. Can be set. In the case where the water discharge element 33 is used at a shallow water depth, the water discharge element 33 can be prevented from being held by the water bottom by increasing the height of the water discharge element 33. Of course, in the present invention, contrary to the present embodiment, the height of the water discharge element 33 is made higher than that of the water absorption element 31, so that water near the bottom of the water is sucked into the pump unit 3 and then close to the water surface. The water can also be discharged.
[0072]
  In parallel with or separately from the above-described water quality improvement processing, the water quality inspection of the water area where the water treatment apparatus A is set can be performed by operating the water quality inspection apparatus 6. The inspection result data is transmitted to the monitoring device 90. Therefore, by checking the data, it is possible to determine whether or not the water quality has been improved to a certain level or more, and decide whether or not to continue the water quality improvement process at the initial setting location. be able to. Of course, since it is also possible to perform a water quality test using the water quality testing device 6 before starting the water quality improvement process, the test result before the water quality improvement process is compared with the test result after the water quality improvement process. By doing so, you can also know how much the water quality has been improved. As described above, the position of the water treatment apparatus A can be measured by the position measuring unit 74, and the data is transmitted to the monitoring apparatus 90. Therefore, the data of the result of the water quality test is the water quality of any place. It is possible to know whether it is the data.
[0073]
  After finishing the water quality improvement process in the vicinity of the initial setting location, the destination of the subsequent water treatment device A is set by the monitoring device 90, and the data of the destination is sent together with a control command for moving the water treatment device A. Transmit to water treatment device A. Then, under the control of the control unit 70, the water treatment apparatus A moves to the designated destination. At this destination, water quality improvement processing is performed as in the case of the initial setting place. In this way, if the water quality improvement process is performed at various locations in the water area while sequentially moving the water treatment apparatus A in the reservoir, the water quality in the entire reservoir area can be improved efficiently. Further, the number of water treatment apparatuses A is small, and the cost of the entire system can be reduced.
[0074]
  The operation of each part of the water treatment apparatus A can be remotely operated by the monitoring device 90, and the water treatment apparatus A can be moved to a desired designated position by automatic control, so that the operation is easy. Furthermore, each time the water treatment device A is moved, a water quality test is performed at the moving location, and the inspection result can be confirmed by the monitoring device 90, which is convenient for grasping the water quality status of the reservoir. . As shown in FIG. 5, the data obtained by the monitoring device 90 can be transmitted to other terminal devices 92 connected via a communication network, and promotes provision of information on water quality improvement of the reservoir. You can also
[0075]
  In the water treatment apparatus A, since the electric energy obtained from the solar cell is used as the power source of each part, unlike the case of using an engine-driven generator that exhausts exhaust gas, for example, from the viewpoint of environmental protection. Even preferable. Moreover, since it becomes unnecessary to supply electric power using a cable from the outside, it can be used regardless of the place where the water treatment apparatus A is used, which is more convenient for use. Furthermore, when the power supply cable is used, when the water treatment apparatus A is moved by the operation of the pump 30, there is a great restriction on the moving distance or the like. It can be something that does not exist.
[0076]
  When the water treatment apparatus A is in use, if a malfunction such as a decrease in the voltage of the rechargeable battery 71 or an abnormal increase in the predetermined pressure due to clogging of foreign matter in the pump unit 3 or the like occurs, the monitoring apparatus 90 is notified accordingly. The Therefore, it is possible to quickly respond to such abnormal situations. As described above, the clogging of the foreign matter can be dealt with by switching the water flow direction in the pump unit 3 by reversing the pump 30.
[0077]
  6 and 7 show another example of the water treatment apparatus according to the present invention. In these drawings, the same or similar elements as those of the above embodiment are denoted by the same reference numerals as those of the above embodiment.
[0078]
  As clearly shown in FIG. 6, in the water treatment device Aa of this embodiment, a mechanism for rotating the pump unit 3 around the vertical axis is not provided, and the water absorption element 31 of the pump unit 3 is provided. Each part such as the water discharge element 33 is fixed. Since each part of the pump unit 3 is fixed, the motor M1 is also fixedly attached in the float 1. Further, as a means for introducing air into the tube body 55, the air introduction hole 11 provided in the float 1 and the tube body 55 are connected using a tube body 56.
[0079]
  In this water treatment apparatus Aa, since the direction of the water inlet 31a and the water outlet 33a cannot be changed, the moving direction of the water treatment apparatus Aa cannot be controlled. Therefore, when using this water treatment apparatus Aa, as shown in FIG. 7, the stay 35b is connected to the pile 90 or weight driven into the bottom of the water via the lead 91, for example. If it does in this way, water treatment apparatus Aa will advance by the circular locus | trajectory centering on the pile 90 or a weight, and water treatment apparatus Aa can be moved in a fixed range by such a method. By changing the length of the lead 91, it is possible to adjust the size of the movement range of the water treatment device Aa. Moreover, when the water quality improvement of a certain water area is complete | finished, the water treatment apparatus Aa can be moved to the next position with the pile 90 or the weight, and the new water quality improvement process in the water area can be performed. Therefore, even when this water treatment apparatus Aa is used, the water quality improvement of the entire reservoir is promoted as compared with the case where water is pumped only from a certain location of the reservoir and the treatment is performed.
[0080]
  The content of the present invention is not limited to the above-described embodiment. The specific configuration of each part of the water treatment apparatus according to the present invention can be modified in various ways.. waterIt is convenient if the processing device can be remotely operated, but such a configuration is not necessarily required. Moreover, it is preferable to provide a water quality inspection device in the water treatment device, but such an accessory device is not necessarily provided.
[0081]
  The water quality improvement unit referred to in the present invention is not limited to the above-described water quality improvement unit, but is a unit in which an electrode for electrolysis is provided in the casing, a unit in which ultrasonic generation means is provided in the casing, and a casing. Various units such as a unit provided with a far infrared irradiation means can be used. A unit in which the water quality can be improved by filling the casing with ceramic can also be used. A plurality of types of units can also be used in combination.
[0082]
  The device for power generation mounted on the float is not limited to a solar cell, and other means such as power generation using wind power can also be used. Although the specific kind of power generation means is not ask | required, it is preferable to use the means which does not produce exhaust gas etc. The specific type of pump used in the pump unit is not limited.
[0083]
  In the above-described embodiment, the case where the water quality of the reservoir is improved has been described as an example, but the specific usage of the water treatment apparatus according to the present invention is not limited to this. In the present invention, it can be used for various water quality improvement applications such as pools, aquariums or domestic water tanks, including lakes and seas other than reservoirs. The overall size of the water treatment apparatus, the capacity of the pump, and the like are appropriately changed in design according to the application.
[0084]
[Brief description of the drawings]
FIG. 1 is a perspective view showing an example of a water treatment apparatus according to the present invention.
FIG. 2 is a cross-sectional view of the water treatment apparatus shown in FIG.
3 is a cross-sectional view showing a schematic structure of a water quality improvement unit used in the water treatment apparatus shown in FIG.
4 is a schematic block diagram of the water treatment apparatus shown in FIGS. 1 and 2. FIG.
FIG. 5 is an explanatory diagram showing an example of a system when a water treatment method according to the present invention is carried out.
FIG. 6 is a cross-sectional view showing another example of the water treatment apparatus according to the present invention.
7 is a perspective view of the water treatment device shown in FIG. 6. FIG.
[Explanation of symbols]
  A, Aa Water treatment equipment
  M1, M2 motor
  1 Float
  2 Solar panel
  3 Pump unit
  4 Water quality improvement unit
  6 Water quality inspection equipment
  55 Tube for introducing air
  30 pumps
  31a Water intake
  31b Water outlet
  70 Control unit
  71 Rechargeable battery
  72 Voltage measuring instrument
  73 Wireless communication unit
  74 Position measurement unit
  75 Pressure sensor

Claims (13)

That can float in the water float,
As well as the position from the float downward, it is rotatably supported around a vertical axis with respect to the float, and rotatably driven rotary member, and,
It is supported by the rotary member, and a water inlet located in the lower than the upper Symbol float, a pump, a water quality improvement unit water therein configured to allow the water quality improvement by passing, than the float lower in conjunction with and a spout facing away with the water inlet, by the operation of the pump, Ponpuyuni' bets water is water from the water inlet is discharged from the water discharge port through the water quality improving unit,
It has been provided with a,
With propulsion by at least one of the action of the water discharge from the water discharge port of the water and the pump unit from the water inlet of the pump unit is generated, by rotating the said rotary member with respect to the float, the A water treatment apparatus configured to change the direction of propulsive force.   The water treatment apparatus according to claim 1, comprising at least one of a rechargeable battery and a power generation means such as a solar battery as a power supply source for the pump unit.   The water treatment apparatus according to claim 1, wherein the water treatment apparatus is configured to be able to turn on and off the operation of the pump unit and change the direction of the propulsive force by remote operation.   The water treatment apparatus according to any one of claims 1 to 3, further comprising a water quality inspection device and a communication unit that wirelessly outputs data of a result of the water quality inspection performed by the water quality inspection device.   5. The apparatus according to claim 4, further comprising position measuring means capable of measuring its own position, and the position data measured by the position measuring means being wirelessly output by the communication means. Water treatment equipment.   When the communication means receives a predetermined command signal for the destination, the on / off operation of the pump unit and the direction of the propulsive force are controlled so that the water treatment device is moved toward the destination. The water treatment apparatus according to claim 5, further comprising a control unit that performs the control.   7. An inspection means capable of inspecting certain items relating to the water treatment apparatus is provided, and data of the result of the inspection performed by the inspection means can be wirelessly output by the communication means. The water treatment apparatus in any one of.   The water treatment apparatus according to any one of claims 1 to 7, wherein the pump unit is capable of sucking external air and discharging the sucked air into water. The water inlet and the height of the ejection Mizuguchi of the pump unit is different from each other, water treatment apparatus according to any one of claims 1 to 8.   The water treatment device according to claim 9, wherein the height of at least one of the water inlet and the water outlet is changeable.   The water treatment device according to any one of claims 1 to 10, further comprising control means for performing control to reversely rotate the pump of the pump unit when a predetermined condition is satisfied.   The water quality improvement unit has a cylindrical casing and a plurality of magnets accommodated in the casing, and a magnetic field that generates magnetic lines of force in a direction intersecting the water flow between the plurality of magnets. The water treatment apparatus according to any one of claims 1 to 11, wherein the water flow path is formed with a water channel.   The water quality improvement unit includes a unit in which an electrode for electrolysis is provided in a casing, a unit in which ultrasonic generation means is provided in the casing, and a unit in which far infrared irradiation means is provided in the casing. The water treatment apparatus according to any one of claims 1 to 12, which is either.

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