JP2021143846A - Backflow detection device and backflow detection system - Google Patents

Abstract

To provide a backflow detection device for detecting a backflow passing through a drain path.SOLUTION: A backflow detection device 10 includes: a sensor section 11; a determination section 26 which is electrically connected to the sensor section 11 and determines presence/absence of occurrence of a backflow on a drain path based on an output of the sensor section 11; an output section 28 which is electrically connected to the determination section 26 and outputs information based on an instruction from the determination section 26; and an attachment section 15 which can attach the sensor section 11 to a desired backflow detection position.SELECTED DRAWING: Figure 1

Description

The present invention relates to a backflow detection device and a backflow detection system.

In buildings such as detached houses and condominiums, drainage facilities, drainage basins, public basins, sewage pipes, and drainage pipes connecting each part form a series of drainage routes.
When a backflow of drainage occurs, the backflow drainage overflows into the living space after reaching the drainage facility. Causes of backflow include those caused by clogging in the drainage channel and those caused by exceeding the drainage allowance of the sewer. In particular, in recent years, there have been increasing opportunities for heavy rains such as guerrilla rainstorms and typhoons to occur at once, and there are concerns about backflow due to excess drainage capacity of sewers.

Here, when the drainage allowance of the sewer is exceeded, a part of the backflow drainage goes to the rising space of the manhole or to the drainage route in the building. Therefore, Patent Document 1 describes a technique including detection and an alarm so that when an abnormal water level in a manhole is detected, the backflow situation can be known.

Patent Document 1 describes an abnormal water level detecting device including a float switch for detecting a water level, an alarm transmitting device for transmitting an alarm sound according to the operation of the float switch, and a reset switch for stopping the alarm sound. A device installed in a manhole that can alert at least that a backflow is occurring in the sewer is disclosed.

Japanese Unexamined Patent Publication No. 2016-156758 Japanese Unexamined Patent Publication No. 2016-199943

By the way, in recent years, as a measure to prevent backflow, a valve body (so-called backflow prevention valve) for preventing backflow to the drainage facility has been installed at the inflow port of the basin on the drainage path (for example). Patent Document 2). This valve body prevents backflow from the sewer pipe or mass to the building side during heavy rain, and backflow from the sewer pipe can be prevented by installing this valve body.
On the other hand, as long as the water supply is not stopped in the building, the drainage system can be used as usual. In this case, the drainage is gradually stored in the drainage path on the upstream side of the installed valve body, and flows back to the inside of the residential area in order from the drainage facility on the lowest lower floor. As described above, the drainage route separated from the sewer pipe cannot be dealt with by the technique of Patent Document 1. Therefore, in order to protect the residential / living space from the backflow that overflows through the drainage route, it is necessary to develop a new means for detecting the backflow situation.
Therefore, the present inventors have earnestly studied new problems that cannot be solved by the above-mentioned Patent Document 1, and have reached the present invention.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a backflow detection device capable of detecting backflow via a drainage path, and a resident using the backflow detection device. It is to provide a backflow detection system capable of reporting predetermined information to the like.

In order to solve the above problems, the backflow detection device according to the present invention has the following features.

(1) The backflow detection device according to the present invention includes a sensor unit, a determination unit that is electrically connected to the sensor unit, and a determination unit that determines whether or not a backflow has occurred in the drainage path based on the output of the sensor unit. It is provided with a transmission unit that is electrically connected to the determination unit and transmits information to the outside based on an instruction from the determination unit, and an attachment unit that can attach the sensor unit to a desired backflow detection position. It is a feature.

According to the configuration of (1), when the situation in the drainage path is detected by the sensor and the judgment unit determines that the backflow has occurred, the information that the backflow has occurred is transmitted to the outside. This backflow detection device can be mounted at a desired backflow detection position by the mounting portion. As a result, by detecting the transmission of the backflow detection device from the outside, it is possible to detect that backflow is occurring at any of the locations.
Therefore, the backflow detection device according to the present invention can detect backflow through the drainage path.

(2) In the backflow detection device according to (1), it is preferable that the mounting portion is mounted from the outside with respect to the drainage path.

According to the configuration of (2), it is attached from the outside to the drainage path. More specifically, it is installed in a place such as a pipeline or a rising part on the drainage route, but by attaching the sensor part to the outside, the sensor part is not immersed in the drainage and can be configured so as not to be contaminated. .. Therefore, the sensor unit of the backflow detection device can be continuously used.
Therefore, the backflow detection device according to (2) can continuously use the sensor unit of the backflow detection device without worrying about contamination by wastewater.

(3) In the backflow detection device according to (1) or (2), the sensor unit is composed of a plurality of sensors, and the mounting unit is formed so that each sensor can be independently installed in the drainage path. Is preferable.

According to the configuration of (3), the sensor unit is composed of a plurality of sensors, and the mounting unit allows each sensor to be installed independently. Therefore, for example, the sensors can be installed at two locations on the drainage route, one on the upstream side and the other on the downstream side, with the sensors separated by a predetermined distance. At this time, if the sensor on the downstream side detects the drainage and then the sensor on the upstream side also detects the drainage, it can be determined that the backflow is detected instead of the mere jumping of the drainage. That is, it is possible to identify the location where the backflow occurs in the drainage path.
Therefore, the backflow detection device according to (3) can improve the accuracy of backflow detection by using a plurality of sensors.

Further, in order to solve the above problems, the backflow detection system according to the present invention has the following features.

(4) The backflow detection system according to the present invention receives the backflow detection device according to (1) to (3), a receiving unit that receives information transmitted from the transmitting unit of the backflow detecting device, and the receiving unit. It includes an information processing unit for performing information processing based on information, and an information management device having a transmission unit for transmitting processed information to a predetermined information terminal according to the information processing.

According to the configuration of (4), in the backflow detection system including the backflow detection device and the information management device, it is possible to report the occurrence of backflow at least in the drainage path. More specifically, after predetermined information processing is performed based on the information received by the receiving unit, the information can be transmitted to the predetermined information terminal.
Therefore, in the backflow detection system according to the present invention, when the backflow detection device detects the backflow in the drainage path, predetermined information can be reported to an information terminal such as a resident.

(5) In the backflow detection system according to (4), the information processing unit may transmit the information after the predetermined processing to at least the resident, the manager, and the information management device installed in another building. preferable.

According to the configuration of (5), the information management device transmits predetermined information to at least the resident, the manager, and the information management device installed in another building. The predetermined information includes, for example, information on how much backflow is occurring in the drainage route, and information on a dangerous place where drainage overflows in the living space.
Therefore, according to the backflow detection system according to (5), the effect described in (4) can be concretely achieved.

As described above, according to the present invention, it is possible to provide a backflow detection device capable of detecting backflow via the drainage path, and the backflow detection device can be used to notify a resident or the like of predetermined information. A detection system can be provided.

It is a drawing which shows typically the structure of the backflow detection system 100 which concerns on this invention. It is a schematic diagram which shows the construction example of the backflow detection apparatus 10 which concerns on this invention, (A) is a figure explaining attachment example 1, (B) is a figure explaining attachment example 2. It is a flowchart which shows the operation flow of the backflow detection system 100 which concerns on this invention. It is a drawing which shows typically the use example of the backflow detection system 100 which concerns on this invention, (A) shows the case where the backflow prevention valve is installed on the upstream side, (B) shows the case where the backflow prevention valve is installed on the downstream side. It is a perspective view which shows the case where it is installed. It is a drawing schematically explaining the operation when a plurality of backflow detection systems 100 according to the present invention are linked, and shows a series of operations from FIG. 5 to FIG. 7, and FIG. 5 shows an initial state. It is a figure which shows the state at the time of the backflow occurrence in FIG. It is a figure which shows the state in which the further backflow is generated in FIG. It is a drawing which shows typically the building building B1 which includes the backflow detection system 100 which concerns on this invention. It is a drawing which shows typically the modification B2 of the building building B1 shown in FIG. It is a drawing which shows typically the rainwater drainage pipe 1I of the building building B3 shown in FIG. It is a drawing which shows typically the detached building B4 which includes the backflow detection system 100 which concerns on this invention.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The embodiments shown below are for better understanding of the gist of the invention, and do not limit the present invention unless otherwise specified. Further, each drawing is shown for easy understanding of the features of the present invention, and the dimensional ratio of each component is not always the same as the actual one.

<Backflow detection system 100>
The backflow detection system 100 according to this embodiment will be described with reference to FIGS. 1 to 4. FIG. 1 is a drawing schematically showing a configuration of a backflow detection system 100 according to the present invention. 2A and 2B are schematic views showing a construction example of the backflow detection device 10 according to the present invention, FIG. 2A is a diagram for explaining mounting example 1, and FIG. 2B is a diagram for explaining mounting example 2. FIG. 3 is a flowchart showing an operation flow of the backflow detection system 100 according to the present invention. FIG. 4 is a drawing schematically showing a usage example of the check flow detection system 100 according to the present invention, (A) shows a case where a check valve is installed on the upstream side, and FIG. 4 (B) shows a check valve. It is a perspective view which shows the case where is installed on the downstream side.

As shown in FIG. 1, the backflow detection system 100 according to the present invention includes a backflow detection device 10 and an information management device 30.
In the backflow detection system 100, the backflow detection device 10 detects the backflow and the information management device 30 notifies the external terminal 70 of the backflow generated in the drainage pipe 1.

In the backflow detection system 100, the backflow detection device 10 and the information management device 30 are connected in a state where information can be exchanged with each other, and are connected via, for example, a network 50.

Examples of the network 50 include the Internet. The network 50 can be connected to the external terminal 70, and a communication network via the network 50 is formed.
The network 50 is not limited to the Internet, and can be appropriately used as long as it is a network capable of two-way communication regardless of whether it is wireless or wired.

The external terminal 70 is intended for a terminal that requires backflow information, and in the present embodiment, a device owned by a resident of a building or a manager of a building can be mentioned. Specific examples of the external terminal 70 include smartphones, mobile phones, PCs, and tablet PCs.
The external terminal 70 is not limited to these, and includes, for example, other terminals owned by a resident of a building, a manager of a building, a security company, an administrative agency, or the like. It is also possible to restrict access to the external terminal 70 as needed.

The backflow detection system 100 can be operated from the external terminal 70 via the network 50. Examples of the operation by the external terminal 70 include changing the address owned by the backflow detection system 100, changing the setting of the detection condition, reporting condition, and instructing the transmission of the operation log.

(Configuration of backflow detection device 10)
The backflow detection device 10 shown in FIG. 1 can detect the presence or absence of backflow in the drainage pipe line 1.
The backflow detection device 10 includes a sensor unit 11, a mounting unit 15, and a control unit 20.
In the present embodiment, the backflow detection device 10 is configured to attach the sensor unit 11 to the drainage pipe line 1 from the outside by the attachment unit 15. The backflow detection device 10 enables non-contact backflow detection.

Since the sensor unit 11 can detect backflow from the outside of the pipe and does not directly touch the wastewater flowing in the pipe, the sensor unit 11 can avoid contamination and damage due to the wastewater.
Further, since the sensor unit 11 is located outside the tube, the sensor unit 11 can be easily replaced due to damage or life.

In the present embodiment, the sensor unit 11 is composed of the first sensor 11A and the second sensor 11B. Each sensor is communicably connected to the control unit 20, and the detection information of each sensor can be transmitted to the control unit 20.
Although the sensor unit 11 has been described as being composed of two sensors in the present embodiment, it may be configured to be composed of two or more sensors.

The first sensor 11A and the second sensor 11B are non-contact type sensors, and in the present embodiment, the capacitance type sensor is used.
The capacitance type sensor captures the fluctuation of the charge distribution and the dielectric constant at the contact position between the sensor and the target portion as an electric signal, and transmits the result. In the capacitance type sensor, for example, the charge state on the surface layer changes before and after the backflow of water adheres (or is immersed) at the measurement position, so that this is set to be sensed.
Although the first sensor 11A and the second sensor 11B use a capacitance type sensor in the present embodiment, they can also be detected by detecting the surface temperature, detecting the surface vibration, and the like, and are heat-sensitive and laser. The use of various sensors such as the type and ultrasonic type is within the scope of design changes.

The mounting portion 15 is for mounting the sensor portion 11 to the pipe.
In the present embodiment, the mounting portion 15 is an independent member (first mounting tool 15A and second mounting tool 15B) so that each sensor can be mounted at a predetermined position.
Specifically, the mounting portion 15 is mounted at a predetermined position in a state where the first sensor 11A is fixed to the first mounting tool 15A of the mounting portion 15 and the second sensor 11B is fixed to the second mounting tool 15B. can. In this way, the mounting portion 15 can be mounted so that the sensors are separated from each other, or the sensors can be mounted at different mounting angles.

Here, as an example of the method of mounting the sensor by the first mounting tool 15A and the second mounting tool 15B, mounting in a state where the sensor is separated by a distance L in the tube axis direction shown in FIG. A mounting method in a state where the angle R is shifted about the tube axis shown in (B) can be considered.

As shown in FIGS. It is easy to distinguish whether the drainage that has just jumped up in the drainage pipe 1 is attached.
Therefore, by installing the first attachment 15A and the second attachment 15B apart from each other, erroneous detection due to the splashing of drainage can be suppressed, and the detection accuracy can be improved.

Although the mounting portion 15 is composed of two members in the present embodiment, the same effect can be obtained if they can be installed separately for a predetermined period of time. Therefore, if a plurality of sensors can be fixed to a single mounting member, the design thereof. It can be said that the modification is within the designable range of the present invention.

The control unit 20 supplies power to the sensor unit 11, and when the sensor unit 11 detects a backflow at the present time, the control unit 20 transmits the backflow to the information management device 30.
Specifically, the control unit 20 transmits that it is in the backflow detection state through each step of S0 to S4 shown in FIG.
The control unit 20 is composed of a reception unit 22, a storage unit 24, a determination unit 26, and a transmission unit 28, and can operate in cooperation with each other.

When the sensing unit 22 starts sensing (S0), electricity is constantly or intermittently supplied to the receiving unit 22, and the receiving unit 22 supplies electricity to the first sensor 11A and the second sensor 11B, respectively, to perform sensing. (S1).
When the receiving unit 22 receives the detection information from the first sensor 11A and the second sensor 11B, the receiving unit 22 notifies the determination unit 26 of the detection information.

The storage unit 24 stores various information such as an identification number of the backflow detection device 10, detection information, a method of determining information in the determination unit 26, and an operation method based on a command from the external terminal 70.

The determination unit 26 determines a predetermined operation for the backflow detection information received from the reception unit 22 and the command from the external terminal 70 according to the method of information determination stored in the storage means 24.
Specifically, when the determination unit 26 first determines that there is detection information from the second sensor 11B during sensing (S1) (S2), there is a risk of backflow in the drainage pipe 1. Judge that there is. In that state, when the receiving unit 22 further determines that there is detection information from the first sensor 11A (S3), the determination unit 26 causes a backflow in the drainage pipe 1 (backflow). It is determined that detection is in progress (S4)).
After that, the determination unit 26 notifies the information management device 30 via the transmission unit 28 that the backflow is being detected (S4), but the information management device 30 performs predetermined information processing (S5). After that, information distribution (S6) is performed to various terminals. Assuming that the series of operations is completed in this way, the determination unit 26 ends the operations (S7).

In the above series of operations, the backflow detection device 10 can be appropriately changed to continuous or periodic operation according to the specifications. Specifically, continuous operation is a flow of returning from the state of backflow detection (S4) to sensing (S1) after the backflow in the pipeline has subsided, without going through the end operation. , It is an operation that enables detection again.
On the other hand, the periodic operation includes the operation of starting up the backflow detection device 10 and investigating the state in the pipeline at predetermined time intervals.

Further, when a command from the external terminal 70 is input via the receiving unit 22, the determination unit 26 executes the command based on the operation method stored in the storage unit 24.
For example, an operation of transmitting an individual identification number of the backflow detection device 10, an operation of reading unique information of the external terminal 70, an operation of restricting access to the storage means 24, and the like can be mentioned.

(Configuration of information management device 30)
The information management device 30 shown in FIG. 1 performs information processing based on the detection information transmitted from the backflow detection device 10, and transmits the result to the external terminal 70.
The information management device 30 is composed of a receiving unit 32 and an information processing unit 34.
Since the receiving unit 32 of the information management device 30 and the information processing unit 34 are each connected to the network 50, bidirectional communication is possible between the backflow detection device 10 and the external terminal 70. ..

The receiving unit 32 receives information from the backflow detection device 10 and the external terminal 70, and transmits the information to the information processing unit 34. Therefore, the information received by the receiving unit 32 includes commands from the external terminal 70 and the like in addition to the detection information.

The information processing unit 34 performs information processing based on the information received by the receiving unit 32. The information processing unit 34 includes a storage unit 36, a transmission unit 38, and an arithmetic element (not shown). The information processing unit 34 performs information processing stored in the storage unit 36 based on the information received from the receiving unit 32.
The information processing unit 34 transmits predetermined information to a predetermined terminal via the transmission unit 38 based on the result of information processing.

The transmission unit 38 transmits information appropriately processed by the information processing unit 34 to a predetermined terminal or the like via the network 50.

The details of the backflow detection system 100 according to the present invention have been described above. Examples of applying the backflow detection system 100 include the device configurations shown in FIGS. 4A and 4B.

In FIG. 4A, the upstream side is in a closed state, and the closed portion 2 is formed. In FIG. 4B, the downstream side is in a closed state, and the closed portion 3 is formed. The closed portion 2 and the closed portion 3 correspond to, for example, a state in which a part of the pipeline is blocked by a check valve or the like.
First, in FIG. 4A, the drainage from the downstream side (that is, the sewer) flows backward, and the backflow FL1 toward the upper floor is generated. On the other hand, in FIG. 4B, drainage from the upstream side (that is, the drainage facility) accumulates, and a backflow FL2 toward the upper floor is generated.
The backflow FL1 and the backflow FL2 generated in these pipelines are detected by the first attachment 15A and the second attachment 15B by a sensor mounted at a predetermined position. In this way, the information detected by the backflow detection device 10 is transmitted to the external terminal 70 via the information processing unit 30 and the network 50.

The backflow detection system 100 described above has been described for use in one backflow detection system 100. Hereinafter, a cooperative operation using a plurality of backflow detection systems 100 will be performed with reference to FIGS. 5 to 7. explain. FIG. 5 is a drawing schematically explaining an operation when a plurality of backflow detection systems 100 according to the present invention are linked, and shows a series of operations from FIGS. 5 to 7, and FIG. 5 shows an initial state. It shows. FIG. 6 is a diagram showing a state at the time of backflow occurrence in FIG. FIG. 7 is a diagram showing a state in which the further backflow in FIG. 6 is occurring.

For example, as shown in FIG. 5, a group in which four backflow detection systems (first backflow detection 100A, second backflow detection 100B, third backflow detection 100C, fourth backflow detection 100D) are installed from the downstream side on the drainage path. An external terminal 70 is connected to the backflow detection system of the above via a network.

The four backflow detection systems are activated and kept in the state of sensing (S1). Under normal conditions, it is confirmed on the external terminal 70 (interface) that the state is "state: not generated" in all systems.

After that, when a backflow occurs in the drainage path due to a flood such as a heavy rain or a typhoon, the backflow state is detected in order from the first backflow detection system 100A on the downstream side. In the backflow detection system 100 of the present invention, as shown in FIG. 6, the reactions of the first sensor and the second sensor of the second backflow detection system 100B are distinguished, and "during the second sensor reaction" and its details thereof. Can also be confirmed.

After that, when the backflow on the drainage path progresses, the detection is performed when the position of the fourth backflow detection system 100D is reached as shown in FIG.
Therefore, it can be confirmed that the danger of further upstream backflow (that is, backflow into the living space) is imminent.

As described above, by using a plurality of the backflow detection systems 100 of the present invention, it is possible to monitor the situation in the drainage pipe 1 at the time of backflow. The drainage route to which the backflow detection system is installed may be one in which the drainage route is branched in the middle, such as a building or a detached building described later, or one in which the drainage route is meandering in the building.

<Building with multiple backflow detection systems 100>
Hereinafter, an operation example when a plurality of backflow detection systems 100 are installed on the building building B1, the building building B2, the building building B3, and the detached building B4 will be described with reference to FIGS. 8 to 11.
FIG. 8 is a drawing schematically showing a building building B1 including the backflow detection system 100 according to the present invention. FIG. 9 is a drawing schematically showing a modified example B2 of the building building B1 shown in FIG. FIG. 10 is a drawing schematically showing a drainage pipe for rainwater of the building building B3 shown in FIG. FIG. 11 is a drawing schematically showing a detached building B4 including the backflow detection system 100 according to the present invention.

(Building Building B1)
As shown in FIG. 8, the drainage pipe 1 of the building building B1 is composed of a sewerage system 1A, a public mass 1B, an underground pit 1C, a drainage facility 1D, a first floor pipe 1F, and a multi-story floor pipe 1G. A plurality of backflow prevention valves 1H (1HA to 1HD from the downstream side) and a plurality of backflow detection systems 100 (100A to 100E from the downstream side) are installed on the drainage pipe line 1.

Normally, there is no backflow from the sewerage 1A side into the building, but when a flood such as heavy rain occurs, if a backflow occurs in the sewerage 1A, drainage flows from the sewerage 1A toward the public mass 1B, and the amount gradually increases. It will increase.
The drainage accumulated in the public mass 1B by a predetermined amount or more starts to flow toward the underground pit 1C side, but the backflow detection system 100A is sensing by detecting this backflow flowing from the downstream to the upstream direction. It switches from (S1) to backflow detection (S4).
Therefore, for example, by operating the check valve 1HA based on this detection information, it is possible to prevent the backflow from the sewerage 1A to the building side (information processing (S5) and information distribution (S6)).

After the check valve 1HA is activated, the wastewater is stored in the public mass 1B, and in the process, the backflow detection system 100B detects this backflow.
Therefore, for example, by setting so that an external terminal can be warned that there is a risk of overflow from the public mass 1B or outflow of the mass lid (information A), the outside possessed by the administrator or the resident It is possible to inform the terminal of the surrounding situation of the building (information distribution (S6)).

On the other hand, the operation of the check valve 1HA prevents the backflow from the sewer 1A to the underground pit 1C side, but the operation of the check valve 1HA blocks the flow path from the building side to the sewer 1A side. ..
Then, the drainage from each drainage facility 1D flows into the underground pit 1C through the first floor pipe 1F and the multi-story floor pipe 1G and is stored. After that, when the predetermined storage amount is exceeded, the drainage in the underground pit 1C flows back in the first floor pipe 1F and the multi-story floor pipe 1G.
Therefore, based on the backflow detection by the backflow detection system 100C installed on the 1st floor piping 1F, the backflow prevention valve 1HB on the 1st floor piping 1F can be operated to prevent the backflow into the living space. can.
Along with this, using the backflow detection system 100C, the underground pit 1C is almost full (Information B), and backflow to the 1st floor piping 1F is occurring (Information C), 1st floor. It is possible to warn the resident of various information such as restrictions on the use of the drainage facility 1D (information D) to the external terminal owned by the manager or the resident, and to inform the situation of the building.

Following the measures taken on the 1st floor piping 1F, it is necessary to consider the backflow from the underground pit 1C to the multi-story piping 1G side. Therefore, as in the case of the response on the first floor, after operating the backflow prevention valve 1HC in response to the detection reaction of the backflow detection system 100D installed on the second floor, the backflow detection system 100E installed on the third floor responds to the detection reaction. Therefore, by operating the check valve 1HD, it is possible to prevent the backflow of the drainage flowing back through the multi-story floor pipe 1G into the living space.
In accordance with this operation, the backflow detection system 100D and the backflow detection system 100E are used to generate backflow on a predetermined floor in the building building B1 (information E), and in the drainage pipe 1 in the building building B1. Various information such as the situation where the storage limit has been reached (Information F) can be warned to the external terminal owned by the manager or the resident, and the situation of the building can be made known.

After the flood damage caused by the heavy rain has subsided, the drainage from the sewer 1 is resumed, and the drainage collected in the public mass 1B is discharged to the sewer 1 side. Then, the backflow detection system 100A and the backflow detection system 100B switch from backflow detection (S4) to sensing (S1). The check valve 1HA is released according to this operation. This makes it possible to discharge the drainage from the underground pit 1C.
Since the downstream side of the underground pit 1C is released, the drainage stored in the first floor pipe 1F and the multi-story floor pipe 1G is discharged by its own weight. Then, the backflow detection systems 100C to 100E switch from backflow detection (S4) to sensing (S1), so that the backflow prevention valves 1HB to 1HD are released according to these operations. As a result, the drainage pipe 1 is restored, and drainage from the drainage facility 1D as usual becomes possible.
In accordance with the operation of the backflow detection systems 100A to 100E, the return information in the drainage pipe 1 in the building building B1 is notified to the external terminal owned by the manager or the resident, so that the return status of the building building can be notified. Can be known.

For drainage from the underground pit 1C in the normal state, for example, a pump (not shown) may be used to drain the water to the outside of the building such as the sewerage system 1A. Even in such a case, the backflow in the drainage pipe 1 can be detected by using the above-mentioned system.

(Building building B2)
The building building B2 is different from the above-mentioned building building B1 in that the underground pit 1C is not provided in the underground portion. Specifically, the first floor pipe 1F and the multi-story floor pipe 1G are connected to the public mass 1B after merging at a predetermined position.
Here, in the building building B2, since there is no underground pit 1C, the drainage from the drainage facility 1D cannot be temporarily stored. Therefore, there is a higher risk that the backflow will reach the residential area as compared with the building B1.
Therefore, by providing a backflow detection and backflow prevention system as in the building B1, the check valve 1HA operates in the event of flood damage such as heavy rain, and the residence passes through the first floor piping 1F and the multi-story floor piping 1G. It is possible to prevent backflow into the space.

(Building Building B3)
Further, the drainage from the building to the sewerage 1A is not limited to the drainage from the drainage facility 1 described above, but also includes rainwater and the like. For example, in the building building B3, the rainwater collected by each drain 1L installed from the roof 1J to the balcony 1K of each room is discharged to the sewer 1A via the rainwater mass 1M. Road 1I is provided.
Here, when flood damage such as heavy rain occurs, drainage cannot be performed in the sewerage system 1A on the downstream side, and rainwater is stored in the rainwater drainage pipe line 1I.
Then, each drain 1L flows back to the balcony 1K side, and the balcony is filled with drainage, so that the living space is flooded as soon as the window is opened. Other than that, there will be damage such as scattering of goods on the balcony and difficulty in blaming the balcony side for escape.

Therefore, the storage status in the rainwater mass 1M is monitored by, for example, the backflow detection system 100G shown in FIG. 10 so that the drainage status in the rainwater drainage pipe 1I can be monitored. The possibility of backflow of rainwater to the ground surface can be detected at least by the presence or absence of the detection reaction by the backflow detection system 100G.
In addition, when rainwater backflow occurs on the upper floor through the rain gutter, after detection by the backflow detection system 100G, detection by the backflow detection system 100I provided under each drain 1L is confirmed in sequence. The situation is detected.

According to the above detection status, for example, the backflow detection system directed the resident to detect an abnormality in the rainwater drainage status by the reaction of the backflow detection system 100G (Information G), and the outflow of the lid of the rainwater mass 1M. Due to the fear (information H), the reaction of the backflow detection system 100H, the backflow in the rainwater drainage pipe 1I (inside the rain gutter) has started (information I), and the reaction of each backflow detection system 100I. , Warns that there is a high possibility of flooding on the balcony 1K on each floor (Information J), and after the flood damage caused by heavy rain has subsided, it will be possible to restore normal drainage in the rainwater drainage pipeline 1I. The details such as the fact (information K) can be made known.

The rainwater drainage pipe 1I may be provided with a check valve 1HE, or an overflow means may be provided at the position. Since it is not necessary to pay attention to the handling of rainwater as compared with the drainage from equipment or the like, it is possible to let the water in the rainwater drainage pipe 1I escape to the outside by an overflow means.

(Detached building B4)
As shown in FIG. 11, the detached building B4 is different from the above-mentioned building building B1 in that a plurality of residential land masses 1N are installed in the drainage pipe 1. Further, pipes from various drainage facilities 1D extending from the building side to the soil are connected to the residential land mass 1N, and a check valve 1HB is provided on the flow path from the residential land mass 1N to the drainage facility 1D. Will be installed. Further, backflow detection systems 100A to 100C are installed on the drainage pipe 1 of the detached building B2, respectively.
When a flood such as heavy rain occurs, a backflow occurs in the sewerage 1A, and the backflow detection system 100A switches from sensing (S1) to backflow detection (S4) by increasing the water through the public mass 1B. After that, the backflow from the sewer 1A is prevented by shutting off the drainage path by the check valve 1HA.

Further, the backflow detection system 100B can also detect the drainage that is going to flow back to the upstream side of the residential land mass 1N, and after the detection, the backflow prevention valve 1HB prevents further backflow.
On the other hand, the backflow detection system 100C installed in the middle of the piping from the first floor to the second floor can detect the drainage flowing back toward the second floor.

After the flood damage caused by the heavy rain has subsided, drainage from the sewerage system 1A will resume, and it will be possible to discharge the drainage accumulated in the public mass 1B, the drainage accumulated in the residential land mass 1N, and the drainage accumulated in the in-house piping. Detached building B4 returns to a normal environment where drainage is possible.

Based on the detection information from the backflow detection systems 100A to 100C, various information from the occurrence of backflow to the completion of recovery, the occurrence of backflow from the sewer (information a), and the ability to monitor which backflow detection system is responding (information a). Information b), backflow is likely to occur up to the upper floors (information c), sewerage system 1A has been restored (information d), drainage of wastewater accumulated in public mass 1B has been completed (information f), and residential land. The fact that the discharge of the wastewater accumulated in the mass 1N is completed (information g) can be obtained by the backflow detection system 100 of the present invention.

As described above, by installing a plurality of backflow detection systems 100, it is possible to monitor the backflow situation in the building from the detection information from the occurrence of the backflow of the sewer to the completion of the return. In addition to these, by installing a check valve, it is possible to prevent backflow at a predetermined position and take mitigation measures against sudden backflow.

Furthermore, by using the backflow detection system 100 for information transmission, the manager and the resident can be alerted to the restriction of the use of the drainage facility 1D according to the situation of the backflow in the building, and the drainage facility 1D due to the occurrence of the backflow. It is also possible to notify the response necessary for disaster countermeasures, such as a blockage operation alert.

Therefore, according to the backflow detection device 10 and the backflow detection system 100 of the present invention, it is possible to detect the backflow passing through the drainage path, and the resident or the like using the backflow detection device 10 is notified of the predetermined information. Is also possible.

1 ... Drainage pipeline, 1A ... Sewerage, 1B ... Public mass, 1C ... Underground pit, 1D ... Drainage facility, 1F ... 1st floor piping, 1G ... Multilayer floor piping, 1H (1HA ~ 1HE) ・ ・ Backflow prevention valve, 1I ・ ・ Drainage pipe for rainwater, 10 ・ ・ Backflow detection device, 11 ・ ・ Sensor part, 11A ・ ・ 1st sensor, 11B ・ ・ 2nd sensor, 15 ・ ・ Mounting part, 15A ... 1st fixture, 15B ... 2nd fixture, 20 ... Control unit, 22 ... Receiver unit, 24 ... Storage unit, 26 ... Judgment unit, 28 ... Transmission unit, 30 ... Information Management device, 50 ... network, 70 ... external terminal, 100 (100A-100I) ... backflow detection system, B1 ... building building, B2 ... building building, B3 ... building building, B4 ... detached building , FL1 ... Backflow, FL2 ... Backflow

Claims (5)

Sensor part and
A determination unit that is electrically connected to the sensor unit and determines whether or not backflow occurs on the drainage path based on the output of the sensor unit.
A transmission unit that electrically connects to the judgment unit and transmits information to the outside based on an instruction from the judgment unit.
An attachment unit that can attach the sensor unit to the desired backflow detection position,
A backflow detection device characterized by being equipped with. The backflow detection device according to claim 1, wherein the mounting portion is mounted from the outside with respect to the drainage path. The sensor unit is composed of a plurality of sensors.
The mounting portion is formed so that each sensor can be independently installed in the drainage path.
The backflow detection device according to claim 1 or 2. A backflow detection system including the backflow detection device according to claims 1 to 3.
With the backflow detection device
A receiving unit that receives information transmitted from a transmitting unit of the backflow detection device, an information processing unit for performing information processing based on the information received by the receiving unit, and processing toward a predetermined information terminal according to the information processing. A backflow detection system including an information management device having a transmission unit for transmitting later information. The backflow detection system according to claim 4, wherein the information management device transmits information after a predetermined process to at least a resident, a manager, and an information management device installed in another building. ..

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