KR20190091980A - A Waterway or Pipeline type Sterilizing Apparatus Using UV - Google Patents

Abstract

The present invention relates to a channel or pipeline type ultraviolet sterilizing device. More specifically, the present invention relates to a channel or pipeline type ultraviolet sterilizing device which can quickly diagnose and inform a failure of each of a plurality of UV lamps, and can block an inflow of foreign substances into a sterilizing module by including a filtering unit for blocking the foreign substances in the front of the sterilizing module, thereby preventing the sterilizing module from being damaged due to the foreign substances or preventing the foreign substances from being attached to or stuck to the sterilizing module to reduce the sterilization efficiency and interfere with the flow of water.

Description

A Waterway or Pipeline type Sterilizing Apparatus Using UV}

The present invention relates to a water channel or pipeline type UV sterilizer, and more particularly, to quickly diagnose and inform a failure of each of a plurality of UV lamps, and sterilization including a filtering unit to block foreign substances in front of the sterilization module. By blocking the inflow of foreign substances into the module, a water or pipe type UV sterilizer which prevents the sterilization module from being damaged or attached to or stuck to the sterilization module, reduces sterilization efficiency and prevents the flow of water. will be.

In the treatment facilities such as sewage, various devices such as a contaminant treatment device and a filtration device for the treatment of water such as sewage to be treated are used. Among them, UV (UV) for sterilization of water to be treated is used. Sterilizers have also been used a lot.

UV sterilizer is to use the sterilization effect of ultraviolet rays by irradiating the water to be treated with ultraviolet rays, as shown in the following patent document, the ultraviolet lamp is installed in the water flow channel or pipe through which sterilization is performed.

However, in order to obtain the sterilizing effect on the water by using the UV sterilizer, even if sufficient irradiation time of ultraviolet rays is required, there is a problem in that the composition is not separately installed so that a sufficient sterilizing effect is not obtained. Even if the change did not cope with this at all, there was a problem of flowing unsterilized water.

In addition, the conventional ultraviolet sterilizer is to remove the foreign matter by installing a cleaning device of the ultraviolet lamp as shown in the patent document below, but foreign matter contained in the sewage, etc. are introduced as it is to damage the UV lamp module or sandwiched between the lamp module. There was a problem that prevented the flow of water.

In addition, conventionally, it is difficult to quickly identify and cope with the failure of the ultraviolet lamp installed in the water, and thus, sterilization of sewage and the like was not performed properly.

(Patent literature)

Registered Utility Model Publication No. 20-0393361 (registered Aug. 11, 2005) "Waterway type UV sterilizer equipped with underwater cylinder and sleeve cleaning device using the same"

The present invention has been made to solve the above problems,

It is an object of the present invention to provide a channel or pipeline type ultraviolet sterilizer for enabling rapid and accurate response to failure of an ultraviolet lamp.

The present invention blocks the inflow of foreign substances into the sterilization module, so that the sterilization module is damaged or the foreign matter is attached to or stuck to the sterilization module, thereby reducing the sterilization efficiency and preventing the flow of water. The purpose is to provide a sterilizer.

The present invention is implemented by the embodiment having the following configuration to achieve the above object.

According to one embodiment of the present invention, a water channel or a pipeline type ultraviolet sterilizer according to the present invention is installed in a water channel or a pipe through which water to be treated flows, a sterilization module for irradiating ultraviolet rays, and a controller for controlling the operation of the sterilizer. It includes, The sterilization module is formed along the longitudinal direction of the waterway or the pipeline to irradiate ultraviolet rays, UV lamp portion is formed a plurality of spaced apart at regular intervals in the width direction and the vertical direction of the waterway or pipeline. The control unit is to diagnose and notify the failure of each ultraviolet lamp unit according to the operating state of each of the ultraviolet lamp unit, it is characterized in that to improve the efficiency of maintenance.

According to another embodiment of the present invention, in the waterway or pipeline type ultraviolet sterilizer according to the present invention, the control unit is a lamp operation control unit for controlling the operation of each of the ultraviolet lamp unit and the operation state of each ultraviolet lamp unit And a failure diagnosis unit for notifying and diagnosing a failure, wherein the lamp operation control unit adjusts the number of ultraviolet lamp units operated according to the water level, and the failure diagnosis unit determines whether each of the ultraviolet lamp units is operated by the lamp operation control unit. The lamp operation information receiving module for receiving information about the current, the current information receiving module for receiving information about the current flowing in the ultraviolet lamp unit to be operated, and the current flowing through each ultraviolet lamp unit to judge the normal operation of each ultraviolet lamp unit. It characterized in that it comprises a lamp-by-lamp normal operation determination module.

According to another embodiment of the present invention, the water channel or the pipeline type ultraviolet sterilization apparatus according to the present invention is characterized in that it comprises a filtering unit is formed at the front end of the sterilization module to block foreign substances flowing into the sterilization module.

The present invention can obtain the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention has the effect of enabling a quick and accurate response to the failure of the ultraviolet lamp by operating a plurality of ultraviolet lamps in accordance with the water level to enable efficient sterilization, and to diagnose and inform the failure of each ultraviolet lamp. .

The present invention includes a filtering unit to block foreign substances in the front of the sterilization module, by blocking the inflow of foreign substances into the sterilization module, the sterilization module is damaged by the foreign substances or attached to the sterilization module, the sterilization module is reduced sterilization efficiency and water flow There is an effect to prevent the interference.

1 is a block diagram of a waterway or pipeline type ultraviolet sterilizer according to an embodiment of the present invention
2 is a front view of the sterilization module of FIG.
3 is a cross-sectional view taken along the line AA of FIG.
4 is a cross-sectional view showing an example of installation of the sterilization module of FIG.
5 is a view showing the ultraviolet lamp unit and lamp sealing means of FIG.
6 is a block diagram illustrating a configuration of a controller of FIG. 1.
7 is a block diagram of a water channel or a pipeline type ultraviolet sterilizer installed with a water level control unit
8 is a cross-sectional view of the water level adjusting unit of FIG.
9 is a side view of the filtering unit of FIG.
10 is a cross-sectional view taken along the line BB of FIG.
FIG. 11 is a cross-sectional view taken along line CC of FIG. 9.
12 is a reference diagram illustrating the pressing plate of FIG. 10.
13 is a cross-sectional view of the pressing member of FIG.
14 is a cross-sectional view showing various embodiments of the fixing plate
15 is a cross-sectional view showing a state in which the fixing plate of FIG. 14 (b) is mounted.
16 is a block diagram showing a configuration of a sensor unit;

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the channel or tube type ultraviolet sterilizer according to the present invention will be described in detail. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Throughout the specification, when a part is said to "include" any component, which means that it may further include other components, except to exclude other components unless specifically stated otherwise, also described in the specification The terms "... unit", "... module" and the like refer to a unit for processing at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software.

UV sterilizer according to the present invention can be applied to both the water flowing through the water to be treated or the pipe formed in the form of a pipe, the following will be described as an example of the water channel, the same can also be applied to the pipe.

Referring to FIGS. 1 to 15, the water channel or the duct-type ultraviolet sterilizer according to an embodiment of the present invention is installed in the water channel (W) through which the water to be treated flows. Sterilization module (1) for irradiating ultraviolet rays, a control unit (2) for controlling the operation of the sterilization device, the water level control unit is formed at the rear end of the sterilization module (1) to adjust the water level passing through the sterilization module (1) (3), a filtering unit (4) formed at the front end of the sterilization module (1) to block foreign substances flowing into the sterilization module (1), and a sensor unit (5) for measuring information necessary for the operation of the sterilization apparatus. It includes.

In the channel or pipeline type UV sterilizer according to the present invention, a sterilization module 1 including a plurality of ultraviolet lamp units 11 is formed in a module form and can be installed in various numbers according to the height and width of the channel W. By doing so, easy installation and efficient operation of the sterilization module (1) is possible. In particular, the plurality of ultraviolet lamp unit 11 is to be controlled in accordance with the water level and flow rate of the water flowing through the waterway (W) to ensure efficient and safe sterilization. In addition, each of the plurality of ultraviolet lamp units 11 may be diagnosed with a failure and lifespan so as to be known to the administrator, thereby managing the sterilization module 1 quickly and accurately.

In addition, the sterilization apparatus according to the present invention can be formed to adjust the water level of the water flowing through the waterway (W) by forming a water level control unit (3) at the rear end of the sterilization module (1), as shown in FIG. Irrespective of the flow rate of the water flowing in the water channel (W), it is possible to sufficiently irradiate the ultraviolet light to the water.

And the front of the sterilization module 1 to form a filtering unit (4) to prevent foreign substances from entering the sterilization module (1), thereby preventing problems such as damage to the sterilization module (1) or lower sterilization efficiency The filtering unit 4 may be easily replaced even if the filter 4 is damaged so that efficient management can be made.

The sterilization module 1 is configured to sterilize by irradiating ultraviolet light to the water flowing through the water channel (W), as shown in Figures 2 to 3 a module form including a plurality of ultraviolet lamp unit 11 It is formed to be installed according to the width and height of the channel. To this end, the sterilization module (1) is formed in the vertical direction on both ends of the upper frame 12 and the upper frame 12 is formed along the longitudinal direction of the ultraviolet lamp portion 11 having a predetermined width; It includes a support frame 13 for supporting the ultraviolet lamp unit (11). Therefore, the plurality of UV lamps 11 may be formed at regular intervals between the support frames 13, and a plurality of UV lamps 11 may be formed in the vertical direction and the left and right directions. As shown in FIG. 4, the sterilization module 1 including the plurality of ultraviolet lamp units 11 is formed in plural according to the width and width of the waterway, and the entire water flowing through the waterway regardless of the width and width of the waterway. Sterilization can be performed for.

The ultraviolet lamp unit 11 is formed in plural at a predetermined interval in one sterilization module (1), as shown in Figure 5 sealed the ultraviolet lamp 111 and the ultraviolet lamp 111 for irradiating ultraviolet light water Lamp sealing means 112 to avoid contact with.

The ultraviolet lamp 111 is configured to generate ultraviolet light according to the supply of current, and is inserted into the lamp sealing means 112 in the form of a lamp to configure the sterilization module 1. In particular, the ultraviolet lamp 111 is operated under the control of the control unit 2, the operation is adjusted according to the water level in the waterway (W), the operation is also depending on the flow rate of water flowing through the waterway (W). Allow it to be adjusted. In addition, the control unit 2 can determine whether the normal operation of each ultraviolet lamp 111 and the remaining life can be notified to the administrator, so that the management of the ultraviolet lamp 111 can be made accurately and quickly. Detailed description thereof will be described later.

The lamp sealing means 112 is configured to seal the ultraviolet lamp 111 so that it does not come into contact with the water, the sleeve 112a for receiving the ultraviolet lamp 111, the lamp coupled to the open one surface of the sleeve 112a The holder 112b may include a sealing nut 112c coupling the lamp holder 112b and the sleeve 112a, and a sealing o-ring 112d inserted between the sealing nut 112c and the sleeve 112a.

The sleeve 112a is configured such that only one surface of the sleeve 112a is opened so that the ultraviolet lamp 111 may be accommodated. The open surface of the sleeve 112a may be in close contact with the lamp holder 112b. In addition, an illuminance sensor 112a-1 for measuring illuminance of the ultraviolet lamp 111 may be formed in the sleeve 112a, and the ultraviolet ray may be formed according to the illuminance information measured by the illuminance sensor 112a-1. The failure of the lamp 111 and the remaining life is determined to be known to the administrator.

One end of the lamp holder 112b is in close contact with the sleeve 112a and is coupled by the sealing nut 112c, and a power line is inserted into the other end thereof to be connected to the ultraviolet lamp 111. In addition, one end of the lamp holder 112b is formed with a screw thread to be coupled to the sealing nut (112c).

The sealing nut 112c is coupled to the lamp holder 112b so that a close coupling between the lamp holder 112b and the sleeve 112a is achieved. The sealing nut 112c forms a screw thread inwardly so as to be combined with the threaded acid of the lamp holder 112b, and the sealing o-ring 112d is inserted between the sleeve 112a to form a tight seal. The sealing nut 112c may be preferably made of polyethylene (PE), thereby preventing breakage of the ultraviolet lamp 111 and reducing the weight of the ultraviolet lamp part 11.

The sealing o-ring 112d is inserted between the lamp holder 112b and the sealing nut 112c, and is inserted between the sleeve 112a. The sealing o-ring 112d is fitted into the sealing nut 112c so that the sealing o-ring 112d is tight. Make it possible to seal.

The control unit 2 is configured to control the operation of the ultraviolet sterilizer according to the present invention, as shown in Figure 6 lamp operation control unit 21 for controlling the operation of the ultraviolet lamp 111, to diagnose the failure The failure diagnosis unit 22, the life diagnosis unit 23 for diagnosing the life, and the level control plate operating unit 24 for adjusting the operation of the water level control unit (3).

The lamp operation control unit 21 is configured to control the operation of the ultraviolet lamp 111, to adjust the operation of each of the plurality of ultraviolet lamps 111. As described above, the UV lamps 111 are formed in the sterilization module 1 in a plurality of spaced apart from each other in the vertical direction and the width direction, and the sterilization module 1 is attached to the sterilization module 1 according to the depth and the width of the channel W. Can be formed. At this time, the lamp operation control unit 21 measures the level of water flowing in the waterway (W) to control the operation of the ultraviolet lamp 111, so that only the ultraviolet lamp 111 in the water to operate. Therefore, the ultraviolet lamp 111 outside the water can be prevented from operating so as to minimize the external exposure of the ultraviolet light, and the energy can be saved by using the ultraviolet lamp 111 efficiently. In addition, the lamp operation control unit 21 may adjust the operation of the ultraviolet lamp 111 according to the flow rate of the water flowing through the waterway (W). According to the present invention, the flow rate sensor 52 is formed at the outlet O of the waterway W, so that the flow rate of the water discharged from the waterway W can be measured, and based on this, the operation of the ultraviolet lamp 111 is performed. This can be adjusted. In other words, when the flow rate of the water discharged from the waterway W is small, the lamp operation control unit 21 operates only a part of the ultraviolet lamp 111 in the water because the speed of the water flowing through the waterway W is slow. In order to prevent unnecessary power consumption, and if the flow rate is large, it means that the speed of the water flowing through the waterway (W) is fast, so that the number of ultraviolet lamps 111 among the ultraviolet lamps 111 in the water is increased to sterilize. Try to increase the effect. Therefore, the lamp operation control unit 21 to operate only the ultraviolet lamp 111 of a predetermined height or less according to the water level, and by controlling the number of ultraviolet lamps 111 that operate according to the flow rate, efficient use and sterilization of power. This can be done. To this end, the lamp operation control unit 21 is a water level information receiving module 211 for receiving the water level information from the water level sensor 51 to be described later, a flow rate information receiving module for receiving information about the flow rate from the flow sensor 52 212, the operation lamp determination module 213 for determining the ultraviolet lamp 111 to be operated based on the water level information and the flow rate information, and a lamp operation module 214 for operating the determined ultraviolet lamp 111.

The failure diagnosis unit 22 is configured to diagnose and notify the failure of each ultraviolet lamp 111, the operation information of the ultraviolet lamp 111 by the lamp operation control unit 21 and the current flowing in the ultraviolet lamp 111 To determine whether the failure of each ultraviolet lamp 111. However, the failure diagnosis unit 22 is not limited thereto, and may compare the illumination information of each ultraviolet lamp 111 to determine whether it is in normal operation. The failure diagnosis unit 22 includes a lamp operation information receiving module 221 for receiving operation information of each ultraviolet lamp 111 and a current information receiving module 222 for receiving information about a current flowing through each ultraviolet lamp 111. ), Failure lamp notification notifying whether or not the normal operation status determination module 223 for each lamp to determine whether the normal operation by comparing the operation information of the ultraviolet lamp 111 and the information on the current flowing through each of the ultraviolet lamp 111. Module 224.

The lamp operation information receiving module 221 is determined by the UV lamp 111 to be operated by the lamp operation control unit 21, the UV lamp 111 is operated when the operation of the UV lamp 111 for this is made. Receive information about The lamp operation information receiving module 221 transmits the operation information of the received ultraviolet lamp 111 to the lamp-specific operation determination module 223 for each lamp to determine whether there is a failure.

The current information receiving module 222 receives the information on the current flowing through each ultraviolet lamp unit 11 when the ultraviolet lamp 111 is operated by the lamp operation control unit 21. The current information receiving module 222 may receive information about a current value, a voltage value, a power value, etc. from a sensor (not shown) formed in each of the ultraviolet lamp units 11 to measure a current flowing therein. By receiving one value, it is possible to determine whether the normal operation of each UV lamp unit (11).

The normal operation status determination module 223 for each lamp may include operation information of the ultraviolet lamp 111 received by the lamp operation information receiving module 221 and information on the current received by the current information receiving module 222. By using it to determine whether or not each of the ultraviolet lamp 111. The normal operation operation determination module 223 for each lamp may determine whether the operation is normal based on any one of a current value, a voltage value, and a power value of the current flowing through each of the ultraviolet lamps 111. In other words, the operation of the lamp-specific normal operation determination module 223 has been given an operation instruction by the lamp operation control unit 21, but the information on the current received by the current information receiving module 222 has a predetermined value. In the following case, or when the current is more than a certain degree even though the operation instruction is not made by the lamp operation control unit 21, to determine the ultraviolet lamp 111 as a failure. Therefore, the normal operation of each lamp determination module 223 for each lamp can detect all the cases until the operation is not performed by a failure or an error occurs in the control system and the control signal is incorrectly transmitted.

The failure lamp notification module 224 is configured to notify a manager or the like about information on the ultraviolet lamp 111 determined to be a failure by the normal operation determination module 223 for each lamp, by a separate display device. The failed ultraviolet lamp 111 may be displayed, or may be displayed by transmitting failure information to a terminal such as an administrator.

The life diagnosis unit 23 is configured to calculate and notify the remaining life of each ultraviolet lamp 111, so as to compare the initial current information of each ultraviolet lamp 111 with the current information measured during operation. To this end, the life diagnosis unit 23 is the initial current information storage module 231, current information receiving module 232 for each lamp, remaining life calculation module 233, remaining life display module 234, replacement notification module ( 235).

The initial current information storage module 231 is configured to store initial current information of each ultraviolet lamp 111, and may store initial information based on any one of a current value, a voltage value, and a power value. have.

The lamp-specific current information receiving module 232 is configured to receive information regarding a current flowing through each of the ultraviolet lamps 111, and any one of a current value, a voltage value, and a power value, similar to the current information receiving module 222, is used. To receive information.

The remaining life calculation module 233 is configured to calculate the remaining life of each ultraviolet lamp 111, the information such as the initial current value stored by the initial current information storage module 231 and the current information receiving module for each lamp Comparing the information such as the current value flowing through the ultraviolet lamp 111 received by 232 to calculate the remaining life according to the ratio.

The remaining life display module 234 is configured to display the remaining life of each ultraviolet lamp 111 calculated by the remaining life calculation module 233, and delivers the remaining life information to a separate display device or a separate terminal. Can be displayed.

The replacement notification module 235 is configured to notify an administrator, etc. when the remaining life calculated by the remaining life calculation module 233 is less than or equal to a set value, and transmits a notification signal to a separate display device or terminal. Through this, it is possible to make a quick replacement for the UV lamp 111 at the end of its life.

The water level control plate operating unit 24 is configured to adjust the operation of the lifting means 33 to be described later of the water level adjusting unit 3, the height of the water level adjusting plate 31 is adjusted through the operation of the lifting means (33). Be sure to The water level control unit 3 is formed at the rear end of the sterilization module 1 to adjust the water level of the water flowing through the waterway (W), that is, the water level passing through the sterilization module 1, the water level protruding upward from the bottom The adjusting plate 31 is formed so that its height is adjusted. Therefore, the water level of the water flowing through the waterway W is determined according to the extent to which the level control plate 31 protrudes upward from the bottom. The level control plate operating unit 24 is configured to control the operation of the lifting means 33 for elevating the level control plate 31, the height of the level control plate 31 is adjusted according to the flow rate of the water flowing through the waterway (W) You can do that. To this end, the level control plate operating unit 24 is an optimum flow rate setting module 241 for setting an optimum flow rate for sterilizing water, flow rate information receiving module 242 for receiving flow rate information from the flow rate sensor 52, It includes a water level calculation module 243 for estimating the water level for adjusting the optimum flow rate, and a water level control plate operation module 244 for operating the water level control plate 31 according to the calculated water level.

The optimum flow rate setting module 241 is configured to set the information on the optimum flow rate for maximizing the sterilization effect by the ultraviolet lamp 111, the outlet O corresponding to the position where the flow sensor 52 is installed Set the flow rate as the reference. The sterilization effect on the water can be maximized only by securing sufficient ultraviolet irradiation time, but if the flow of water is too slow, there is a problem that too much time for sterilization is consumed. Therefore, since the water flowing through the channel must pass at an appropriate speed to balance the sterilization effect and the processing time, the optimum flow rate setting module 241 sets and stores the optimum flow rate information related thereto in advance.

The flow rate information receiving module 242 is configured to receive information about the flow rate from the flow rate sensor 52, and the received flow rate information is transferred to the level calculation module 243 to be compared with the optimum flow rate information.

The water level calculation module 243 compares the optimum flow rate information set by the optimum flow rate setting module 241 with the flow rate information received by the flow rate information receiving module 242 to calculate an appropriate level of the water channel W. do. In other words, if the measured flow rate is greater than the optimum flow rate, increase the water level to increase the time the water stays in the waterway (W) to ensure sufficient irradiation time of ultraviolet rays, and if the measured flow rate is less than the optimum flow rate, By lowering the water flow faster, the treatment time of the water is shortened. Therefore, the water level calculation module 243 may maintain the flow rate of the water flowing through the waterway (W) to the optimum flow rate, to have an optimal sterilization efficiency and processing speed.

The level control plate operation module 244 is configured to operate the level control plate 31 according to the proper level calculated by the level calculation module 243, the level control plate (for operation of the lifting means 33 to be described later) 31) to adjust the height. Therefore, when the level control plate operating module 244 needs to increase the level by comparing the proper level with the current level, it is necessary to raise the height of the level control plate 31 to a height corresponding to the appropriate level, and lower the level. If there is to lower the height of the water level control plate 31 to a height corresponding to the appropriate level.

The water level control unit 3 is configured to adjust the water level of the water passing through the sterilization module 1, so as to be formed on the rear end of the sterilization module 1 as shown in FIG. The water level control unit 3 includes a water level control plate 31 that is lifted from the bottom to adjust the water level of the water flowing through the waterway (W) according to the height of the water level control plate 31, through which sterilization efficiency by ultraviolet irradiation Balance the rate of treatment of water with water. To this end, the water level control unit 3 may include a lifting means 33 for elevating the water level control plate 31, the water level control plate 31, as shown in FIG.

The water level control plate 31 is configured to protrude upward and downward to the bottom of the waterway (W), so that the water level of the water passing through the sterilization module 1 can be formed as protruded to the bottom. The level control plate 31 is elevated by the operation of the lifting means 33, the height is adjusted by the level control plate operating unit 24 in accordance with the flow rate of the water flowing through the waterway (W). As described above, the water level control plate 31 increases the height when the flow rate is greater than the optimum flow rate, and increases the speed of water by lowering the height when the flow rate is less than the optimum flow rate. In addition, when the water level control plate 31 has a very low flow rate and the water level does not reach even the bottom UV lamp 111, the water flows through the water channel W so as to protrude from the bottom by the height of the UV lamp 111 at the bottom. It is possible to prevent the problem of being discharged as it is not exposed to the ultraviolet rays or the ultraviolet lamp 111 being exposed out of the water.

The elevating means 33 is configured to enable the vertical movement of the water level control plate 31, it may be formed in the bottom of the water level control plate 31 is inserted. The elevating means 33 is an elevating cylinder 331 for providing power for elevating the level control plate 31, and an elevating rail 332 formed along an inner wall of the bottom to provide a path for the level control plate 31 to move. The guide member 333 is formed to protrude to both sides of the level control plate 31 to move up and down along the lifting rail 332. Therefore, the elevating means 33 may raise or lower the water level control plate 31 by the operation of the elevating cylinder 331, and guide members 333 such as wheels formed on both sides of the water level control plate 31 are provided. By moving up and down along the lifting rails 332, stable lifting can be achieved.

The filtering unit 4 is formed at the front end of the sterilization module 1 to block foreign substances flowing into the sterilization module 1 so as to be formed in accordance with the width and the width of the channel W. The filtering unit 4 blocks foreign substances of a predetermined size or more introduced into the sterilization module 1, and the sterilization module 1 is damaged by being bumped into the foreign substances or attached to the sterilization module 1 to reduce sterilization efficiency. To solve the problem, such as interfering between the sterilization module (1) to interfere with the flow of water. To this end, the filtering unit 4 includes a plurality of vertical portions 41 formed at regular intervals along the width direction of the channel as shown in FIG. 9; A plurality of horizontal portions 42 formed in a horizontal direction with a bottom surface to connect the plurality of vertical portions 41 to each other; It is formed in parallel with the vertical portion 41, and includes a support portion 43 for supporting the horizontal portion 42 at both ends of the vertical portion 41.

The vertical portion 41 is formed in a plate shape having a predetermined length and thickness, and a plurality of vertical portions 41 are formed to be spaced apart at regular intervals along the width direction of the channel. Therefore, the vertical portion 41 may be caught between the plurality of vertical portion 41 to the foreign matter flowing into the sterilization module (1). The vertical part 41 is fixedly coupled to the horizontal part 42, and the filtering part 4 is particularly coupled to allow detachment of only one vertical part 41. In more detail, the vertical portion 41 is compressed and fixed by the pressing plate 421 to be described later, and can be separated by releasing the pressing of the pressing plate 421. Detailed description will be described later. In addition, the vertical portion 41 may be formed to have various thicknesses of α and β as shown in FIG.

The horizontal part 42 is formed in a horizontal direction with the bottom surface to fix the plurality of vertical parts 41, so that the plurality of vertical parts 41 can maintain a predetermined interval, and each of the vertical parts 41. This separate combination allows the removal of only one vertical portion 41. In addition, the horizontal portion 42 allows only one vertical portion 41 to be detachable, but also enables a firm fixing of the vertical portion 41. The horizontal portion 42 is inserted between each of the plurality of vertical portion 41, the pressing plate 421 for pressing and pressing the vertical portion 41 of both sides; A support plate 423 formed to be in close contact with the back of the pressing plate 421 and supporting the pressing plate 421; A pressing member 422 fastened through the pressing plate 421 and the support plate 423; A fixing plate 424 fixed to an upper end of the support frame 425 so as to protrude toward the front side, and below the portion protruding toward the front side to which the support plate 423 is fixed; And a support frame 425 that is horizontal with the bottom surface and connects the support portions 43.

For reference, for clarity, a portion where water flows is called a front side, and a portion where water flows in a sterilization module 1 direction is referred to as a rear side.

The pressing plate 421 is inserted between each of the plurality of vertical portions 41, and is formed as a plate having a rectangular cross section as shown in FIG. The pressing plate 421 is in close contact with the support plate 423 by the pressing member 422 as shown in FIG. 10, and pushed to both sides by the pressing member 422 having the enlarged portion 422a. Crimp (41). Accordingly, the vertical portion 41 may be pressed by the pressing plate 421 according to the insertion of the pressing member 422 to maintain the state firmly fixed to the horizontal portion 42, and simultaneously hold one pressing member 422. Loosen one vertical portion 41 from the horizontal portion 42. In addition, the pressing plate 421 is formed to be divided into both sides with respect to the point through which the pressing member 422 penetrates as shown in FIG. 12 (b) and is pushed to both sides according to the insertion of the pressing member 422. The vertical portion 41 can be compressed, and the pressing plate 421 is easily installed and dismantled. The pressing plate 421 includes an inlet hole 421a through which the pressing member 422 is inserted.

The inlet hole 421a is a hole formed through the pressing plate 421, and the pressing member 422 is inserted therethrough. The inlet hole 421a forms a space in close contact with the enlarged diameter portion 422a so that the enlarged diameter portion 422a of the pressing member 422 is inserted to push the pressing plate 421 to both sides, and the diameter increases toward the front side. Make a hole. In addition, as described above, the pressing plate 421 is divided into two sides with respect to the inlet hole 421a. In addition, the inlet hole (421a) is formed in a pair spaced apart by a predetermined interval up and down to increase the pressing force for the vertical portion 41 to enable a stable fixing of the vertical portion (41).

The pressing member 422 is inserted through the pressing plate 421 and the supporting plate 423, presses the pressing plate 421 to be in close contact with the supporting plate 423, and a thread is formed along a circumferential surface of the supporting plate ( 423 is coupled to the screw thread formed in the through-hole (423a) to be described later. In particular, the pressing member 422 includes an enlarged diameter portion 422a, the diameter of which is increased toward the end as shown in FIG. 13, and thus the pressing plate 421 is inserted into the inlet hole 421a of the pressing plate 421. Push to both sides to be compressed to the vertical portion (41).

The support plate 423 is in close contact with the rear surface of the pressing plate 421 and is integrally formed by being attached to a fixed plate 424 formed upward. Since the fixing plate 424 is attached to the support frame 425 supported by the support 43, the support plate 423 attached to the fixing plate 424 may maintain a fixed state and the fixed support plate 423 ) Supports the pressing plate 421 to press the vertical portion 41 of both sides. The support plate 423 may be formed in the same shape as the pressing plate 421, and includes a through hole 423a through which the pressing member 422 is inserted.

The through hole 423a is a hole into which the pressing member 422 is inserted, and a screw thread is formed at an inner side thereof so that the through hole 423a may be coupled to the pressing member 422, and an inlet hole 421a of the pressing plate 421 may be formed. It is formed to communicate. In addition, the through hole (423a) is formed on the pressing plate 421 side and the first through hole (423a-1) that is enlarged toward the pressing plate 421 side; And a second through hole 423a-2 formed to communicate with the first through hole on the opposite side of the pressing plate 421 and having a predetermined diameter.

The first through hole 423a-1 refers to a region formed on the pressing plate 421 in the through hole 423a, and the diameter of the first through hole 423a-1 increases toward the pressing plate 421. Accordingly, the enlarged diameter portion 422a of the pressing member 422 may be inserted, thereby deepening the insertion depth of the pressing member 422 and pressing the pressing plate 421 to both sides so that the vertical portion ( Increase the compressive force against 41).

The second through hole 423a-2 communicates with the first through hole 423a-1, and has a predetermined diameter on the opposite side of the pressing plate 421 so that the pressing member 422 is inserted into and fastened. .

The fixing plate 424 is configured to connect the support frame 425 and the support plate 423 so that the support plate 423 can be fixed at a predetermined position, as shown in FIG. 11. And it can be formed on the upper side of the support frame 425. The fixing plate 424 is formed to protrude to the front side, as shown in Figure 14, and the projection 424a to which the support plate 423 is attached to the lower side; It is formed so as to be embedded in a predetermined depth in the front of the protrusion 424a; the insertion groove 424b is inserted into the vertical portion 41; includes.

The protrusion 424a protrudes forward from a portion attached to the support frame 425 so that the support plate 423 can be attached to the lower side. Accordingly, the support plate 423 may be fixed at a predetermined position, and the insertion groove 424b is formed at a predetermined interval in the protrusion 424a.

The insertion groove 424b is formed to be recessed in the protrusion 424a at a predetermined interval so that the vertical portion 41 is inserted. Accordingly, the support plate 423 may be fixed through the fixing plate 424, and at the same time, the vertical portion 41 may be installed by the pressing plate 421. In addition, the insertion groove 424b may include first and second insertion grooves 424b-1 and 424b-2 that are alternately formed at predetermined intervals as shown in FIG. 14B.

The first insertion groove 424b-1 is alternately formed with the second insertion groove 424b-2, and is formed to be deeper than the second insertion groove 424b-2. Therefore, the vertical portion 41 inserted into and installed in the first insertion groove 424b-1 is later than the vertical portion 41 inserted into the second insertion groove 424b-2 as shown in FIG. It is further protruded to the side, in particular, the vertical portion 41 is inserted into the second insertion groove 424b-2 than when the plurality of vertical portions 41 are all projected to the same length between the support frame 425 is Allow it to move forward so that water flows into the space to be advanced. The foreign material is caught between the vertical portions 41, so that water flows into the advanced space of the vertical portion 41 inserted into the second insertion groove 424b-2. Make the flow more smooth.

The second insertion groove 424b-2 is formed to be embedded in a shorter length than the first insertion groove 424b-1, and the vertical portion 41 inserted into the second insertion groove 424b-2 is advanced. It is to make a space to be able to smooth the flow of water.

The support frame 425 is configured to connect between the support portions 43 of both sides, so that the fixing plate 424 is attached to the upper side to be supported.

The support part 43 is formed in parallel with the vertical part 41, and supports the support frame 425 at both ends of the vertical part 41.

Briefly described with respect to the installation and removal of the vertical portion 41, when the damage or abrasion occurs in one of the plurality of vertical portion 41 is required to replace, the pressing member 422 is pulled out the pressing plate 421 After the pressing of the vertical portion 41 is released, only one vertical portion 41 is separated. Then, the new vertical portion 41 is placed at a predetermined position, and the pressing plate 421 is inserted and fixed. Then, the pressing member 422 is inserted to bring the pressing plate 421 into close contact with the support plate 423. The 421 may compress the vertical portion 41 strongly. Therefore, the filtering part 4 can easily replace one vertical part 41 through fastening and releasing of the pressing member 422, and at the same time enables a firm fixing of the vertical part 41.

The sensor unit 5 is configured to collect information for the operation of the sterilization apparatus, the water level sensor 51 for measuring the water level of the water passing through the sterilization module 1, as shown in Figure 16, the outlet O It may include a flow sensor 52 for measuring the flow rate of water discharged through the).

The water level sensor 51 is formed in the waterway (W) to measure the water level, to measure the water level of the water passing through the sterilization module 1 to be transmitted to the control unit (2). The control unit 2 receiving the water level information operates only the ultraviolet lamp 111 below the corresponding water level through the lamp operation control unit 21.

The flow sensor 52 is formed in the outlet (O) of the water channel to measure the flow rate of water passing through the outlet (O), a flow sensor of various methods can be applied. The flow rate sensor 52 measures the amount of water exiting the outlet O per unit time, and adjusts the number of ultraviolet lamps 111 operated through the lamp operation control unit 21, and the water level control plate. Through the operating part 24 to adjust the height of the water level control plate (31).

In other words, when the flow rate measured by the flow sensor 52 is large, it means that the speed of the water passing through the waterway (W) is fast, so as to increase the number of ultraviolet lamps 111 to operate to increase the sterilization effect And, if the flow rate is small, because the speed of the water passing through the waterway (W) is slow, it is possible to save the energy consumed by operating only a part of the ultraviolet lamp 111 of a certain level or less.

In addition, when the flow rate measured by the flow sensor 52 is large, increase the height of the water level control plate 31 to slow down the speed of the water passing through the waterway (W), and when the flow rate is small, the water level control plate 31 Decrease the height of) to speed up the water passing through the waterway (W). Therefore, efficient sterilization and rapid sterilization of water through securing sufficient irradiation time of ultraviolet rays can be achieved.

In the above, the Applicant has described various embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any changes or modifications may be made to the present invention as long as the technical idea of the present invention is implemented. It should be interpreted as falling within the scope of.

1: Sterilization Module 11: UV Lamp 111: UV Lamp
112: lamp sealing means 12: upper frame 13: support frame
2: control unit 21: lamp operation control unit 22: failure diagnosis unit
23: life diagnosis part 24: level control plate operating part
3: level control part 31: level control plate 33: lifting means
4: Filtering Part 41: Vertical Part 42: Horizontal Part 421: Pressing Plate
422: pressing member 423: support plate 424: fixed plate 425: support frame
43: support
5: sensor 51: water level sensor 52: flow sensor

Claims (3)

A sterilization module installed in a water channel or a pipe through which water to be treated flows, and a control unit for controlling the operation of the sterilizer;
The sterilization module,
It is formed along the longitudinal direction of the waterway or the pipeline irradiates the ultraviolet light, UV lamp portion is formed a plurality of spaced apart at regular intervals in the width direction and the vertical direction of the waterway or pipe;
The control unit is a water channel or pipeline type ultraviolet sterilizer, characterized in that to increase the efficiency of maintenance by diagnosing and notifying the failure of each ultraviolet lamp unit according to the operating state of each of the ultraviolet lamp unit. The method of claim 1, wherein the control unit
Lamp operation control unit for controlling the operation of each operation of the ultraviolet lamp unit and a failure diagnosis unit for diagnosing and informing the failure according to the operation state of each ultraviolet lamp unit,
The lamp operation control unit to adjust the number of ultraviolet lamp unit operated according to the water level,
The fault diagnosis unit,
A lamp operation information receiving module for receiving information on whether each of the ultraviolet lamp units are operated by the lamp operation control unit, a current information receiving module for receiving information on a current flowing in the activated ultraviolet lamp unit, and each ultraviolet lamp unit A water channel or a pipeline type UV sterilizer comprising a normal operation status determination module for each lamp to determine whether the normal operation of each ultraviolet lamp unit according to the current flowing in. According to claim 1, wherein the channel or pipe type ultraviolet sterilizer
Canal or pipeline type ultraviolet sterilizer characterized in that it comprises a filter formed on the front end of the sterilization module to block foreign substances flowing into the sterilization module.

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