CN210690605U - Automatic detection system for human urine - Google Patents

Abstract

The utility model provides an automatic detecting system of human urine, it includes control module, collection urine module, detection module, output module and cleaning module. Wherein the control module controls the operation of the whole system and comprises an instruction input unit. The urine collecting module is used for collecting urine to be detected; the detection module comprises a detection probe seat used for detecting the collected urine to be detected and obtaining a corresponding detection report according to a detection result; the output module is used for outputting the detection report, and the cleaning module is used for cleaning system components in the system, through which the urine to be detected flows or is stored. The utility model provides an automatic detecting system of human urine, its automatic collection and subsequent automated inspection in an organic whole that can collect human urine, the effectual process of simplifying whole urine examination, and the operation process is humanized, and user experience is good.

Description

Automatic detection system for human urine

Technical Field

The utility model belongs to the technical field of medical instrument and specifically relates to, one of them human urine automated inspection system, its realization that can be full-automatic detects the collection and subsequent urine of human urine to and then output testing result.

Background

With the rapid development of economy, the living standard of people is increasingly improved, so that the attention of people to the self health is continuously improved; accordingly, health physical examination is gradually scheduled by people, and during physical examination, urine examination is generally included.

The general urine test, so-called "urine biochemical test" in the industry, can be generally performed only by professional personnel in a hospital, and a professional test device is used to perform the urine test according to the urine to be tested provided by the personnel to be tested. The provided urine to be detected is collected by manual operation of a person to be detected, and the operation experience is not humanized.

Furthermore, the whole urine detection process is also manually divided into two stages, one is a urine manual collection stage, and the other is a special detection stage for urine to be detected, so that the whole urine detection process is complicated to operate.

In addition, the two phases involved in the whole detection process are also different in spatial position, and generally, the two phases are respectively located at two places of a toilet and a detection room. This also makes the personnel to be detected need to send it to the detection room of the medical professional for subsequent professional detection after completing the collection of the urine to be detected. On the one hand, the transfer process may cause accidental damage to the urine to be detected, and on the other hand, the transfer process further increases the complexity of the urine detection operation commonly used in the industry and further increases the problem of unsanitary operation.

Therefore, there is a need to develop a new human urine detection system to overcome the drawbacks of the prior art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic detecting system of human urine, its automatic collection and subsequent automated inspection in an organic whole that can collect human urine, the effectual process of simplifying whole urine examination, and the operation process is humanized, and user experience is good.

In order to realize the purpose, the utility model discloses a technical scheme as follows:

an automatic detection system for human urine comprises a control module, a urine collecting module, a detection module, an output module and a cleaning module. Wherein the control module controls the operation of the whole system and comprises an instruction input unit. The urine collecting module is used for collecting urine to be detected; the detection module comprises a detection probe seat used for detecting the collected urine to be detected and obtaining a corresponding detection report according to a detection result; the output module is used for outputting the detection report, and the cleaning module is used for cleaning system components in the system, through which the urine to be detected flows or is stored. When the instruction input unit of the control module receives an external instruction, the instruction input unit informs the urine collection module to start and collect urine, the detection probe seat of the detection module detects the collected urine and outputs a detection result to the output module for output, and the cleaning module cleans used system components according to the instruction of the control module for reuse.

Further, in various embodiments, wherein the urine collection module comprises a toilet, a urine collection assembly, and a urine collection cup; a chamber pot is arranged in the toilet bowl, a urine collecting ditch is arranged on the inner wall of the chamber pot, and a urine collecting port is arranged in the urine collecting ditch; the urine collection assembly comprises a urine collection device, a pipeline and a urine collection mouth are arranged in the urine collection device, and the pipeline is communicated with the urine collection mouth and the urine collection cup; wherein the urine collecting nozzle is also provided with an upper cover which is connected with an electromagnetic valve through a linkage component; after the electromagnetic valve of the urine collection module is electrified, the linkage assembly can be driven to open the upper cover of the urine collection nozzle, so that urine to be detected can enter the urine collection nozzle through the urine collection opening of the urine collection ditch and then flow through the pipeline in the urine collection device to enter the urine collection cup. The toilet bowl can be a toilet bowl or a standing toilet bowl, and is particularly determined according to needs and is not limited.

Further, in different embodiments, the linkage assembly comprises a solenoid valve pull rod, a lever connecting piece and a urine collector lever, and a urine collecting piston is arranged in the urine collector; the electromagnetic valve is electrified to generate magnetic force to drive the electromagnetic valve pull rod to pull towards the direction of the electromagnetic valve, and the pull rod enables the urine collector lever to rotate through the lever connecting piece, so that the urine collecting piston is driven to rise, and the upper cover of the urine collecting nozzle is opened.

Further, in different embodiments, a liquid level sensor is arranged on one side of the urine collection cup; when the urine to be detected in the urine collection cup is collected to a preset liquid level, the liquid level sensor senses the urine and informs the electromagnetic valve to perform power-off operation. At the moment, the electromagnetic valve pull rod is reversely pushed to return to the original point under the action of the lost electromagnetic force, the pull rod is linked with the lever connecting sheet to push the urine collector lever to rotate back to the original position, the urine collecting piston descends, and the urine collecting nozzle upper cover is retracted and the urine collecting nozzle is closed.

Further, in different embodiments, the information sent by the liquid level sensor may also be sent to the control module, and then the control module controls the urine collection module to close, so that the solenoid valve is powered off.

Further, in different embodiments, the urine collecting piston further includes a piston outlet, which is communicated with the conduit in the urine collector, and the collected urine to be detected enters the urine collecting cup through the piston outlet after passing through a urine collecting tube.

Further, in various embodiments, the length of the urine collection groove is one half to one fifth of the perimeter of the inner wall of the chamber of the bedpan.

Further, in various embodiments, the probe base comprises a sensor assembly and a data processing main board, wherein the sensor assembly comprises a sensor moving adapter board, a sensor transmitting board and a sensor receiving board. The sensor mobile adapter plate is used for receiving an externally transmitted detection instruction and conveying the detection instruction to the sensor transmitting plate, the sensor transmitting plate transmits light waves to urine to be detected, the light waves penetrating through the urine to be detected are received by the sensor receiving plate, receiving results are sent to the data processing main board through the sensor mobile adapter plate, and the data processing main board obtains detection results of the urine to be detected through data processing.

Further, in different embodiments, the data processing motherboard may also be divided into the control module, but is not limited to this.

Further, in different embodiments, the detection probe holder comprises a body, the body comprises a first connecting plate, a second connecting plate and a third connecting plate, the second connecting plate and the third connecting plate are symmetrically arranged at two ends of the first connecting plate, a through hole is arranged on the first connecting plate, a groove is arranged on the outer side surface of the first connecting plate, and probe holder glasses are respectively arranged on the inner side surfaces of the second connecting plate and the third connecting plate, which are opposite to each other; the sensor transmitting plate is arranged on the outer side surface of the second connecting plate, the sensor receiving plate is arranged on the outer side surface of the third connecting plate, the sensor moving adapter plate is arranged on the outer side surface of the first connecting plate, and the probe moving adapter plate protective plate is arranged on the sensor moving adapter plate.

Further, in different embodiments, the probe base further includes a positioning magnetic steel, and the positioning magnetic steel is disposed in the groove; the through hole is connected with a driving screw rod, and the driving screw rod is connected with a driving motor. Further, in various embodiments, the detection module further comprises a detection cup for placing the urine to be detected and the detection reagent conveyed therein; the sensor transmitting plate and the sensor receiving plate are respectively communicated with a probe seat glass, the sensor transmitting plate, the sensor receiving plate and the probe seat glass are all positioned at the same height with the detection cup, and the purpose of detecting the liquid in the detection cup is achieved by utilizing the light intensity transmittance of the color of the urine to be detected after the urine to be detected reacts with the added detection reagent.

Further, in various embodiments, the detection module further comprises a detection reagent delivery metering pump, which sucks the detection reagent stored in the detection reagent storage unit and delivers the detection reagent into the detection cup through a reagent distribution pipeline in the probe slide block positioned above the detection cup.

Further, in different embodiments, the urine collecting module further comprises a urine distribution metering pump, which is connected to the urine collecting cup and conveys the urine to be detected in the urine collecting cup to the detecting cup through a distribution pipeline thereof. Further, the detecting cup can comprise a plurality of detecting cups, and then the urine distribution of the detecting cups is carried out through the distributing pipelines of the detecting cups by the urine distribution metering pump, so that a plurality of different urine detecting items can be implemented.

Further, in various embodiments, the cleaning module comprises a first washing pump connected to a first cleaning pipeline, and a cleaning nozzle of the first cleaning pipeline corresponds to the detection cup and the urine collection cup.

Further, in different embodiments, the detection cup and the urine collection cup are disposed on a detection cup holder, the cleaning module further includes a cleaning motor connected to the detection cup holder through a rotating shaft, wherein the first cleaning pipe is located below the detection cup holder, and the cleaning nozzle includes two nozzles respectively corresponding to the detection cup and the urine collection cup; the detection cup support is turned over by the rotation of the cleaning motor to pour waste liquid in the detection cup and the urine collection cup, and cleaning liquid is sprayed out through the cleaning nozzle to wash the detection cup and the urine collection cup.

Further, in various embodiments, the cleaning module further includes a second washing pump connected to a second cleaning pipe, wherein the second cleaning pipe is connected to a washing water inlet of the urine collector, and the washing water inlet is communicated with a pipe disposed in the urine collector.

Further, in various embodiments, the cleaning module further comprises a sewage pump for discharging sewage remaining in the system after each cleaning using the system components is performed. And for the urine distribution metering pump, the urine distribution metering pump can automatically suck clean water to flush the inner part of the urine distribution metering pump and the distribution pipeline connected with the urine distribution metering pump according to instructions.

Further, in various embodiments, the output module includes a display screen and/or a printer.

Further, in various embodiments, the control module and the output module can be implemented in combination by a smart terminal in combination with terminal application software used thereon. For example, the smart mobile terminal includes a smart phone, the instruction input unit is a terminal APP operating software, the display function included in the output module is implemented by a display screen of the smart phone, and the printing function is implemented by a connected printer. In other embodiments, it may also be a computer terminal or an intelligent tablet terminal, which may be determined according to the needs and is not limited.

Further, in various embodiments, the control module is further connected to a storage module, and a database is disposed in the storage module for storing the detection report. Furthermore, the storage module can be a cloud storage module, so that the safety of data storage is ensured.

Further, in different embodiments, the detection module further includes an automatic test paper discharging device, wherein the automatic test paper discharging device drives the transmission rack through a stepping motor to move the sealing door of the test paper box upwards, the test paper discharging port is opened, the stepping motor rotates to drive the power gear of the roller of the test paper roll, the roller of the test paper roll rotates to further output the test paper outwards, when the test paper is discharged for a predetermined distance, the stepping motor is closed to stop the discharge of the test paper, and then the stepping motor drives the transmission rack to seal the sealing door of the test paper box downwards, so that the test paper stored inside is in a sealing state; the urine collection module further comprises a urine distribution metering pump which is connected with the urine collection cup and transmits urine to be detected in the urine collection cup to the upper part of the output detection test paper through a water outlet pipe of the urine collection cup and drops the urine onto the detection test paper, and the detection probe seat detects an area where the urine to be detected drops on the detection test paper.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model relates to an automatic detecting system of human urine, its automatic collection and subsequent automated inspection in an organic whole that collects human urine, the effectual process of simplifying whole urine examination, and operation process hommization, user experience is good.

Further, the utility model relates to an automatic detecting system of human urine can also combine mobile terminal to use, for example, the cell-phone for its convenient operation, the range of application is wide.

Drawings

Fig. 1 is a schematic diagram of a logical structure of an automatic human urine detection system according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a toilet in a urine collection module of the automatic human urine detection system shown in FIG. 1;

FIG. 3 is a schematic structural diagram of a urine collecting component in a urine collecting module of the automatic human urine detecting system shown in FIG. 1;

FIG. 4 is a schematic structural diagram of a detecting probe seat in a detecting module of the automatic human urine detecting system shown in FIG. 1;

FIG. 5 is a schematic view of the probe block of FIG. 4 shown in a further angular configuration;

FIG. 6 is an exploded view of the probe block of FIG. 4;

FIG. 7 is a schematic structural diagram of the automatic human urine detection system shown in FIG. 1; and

fig. 8 is a schematic structural view of the automatic human urine testing system shown in fig. 7 from a further angle.

Detailed Description

The following will describe in further detail a technical solution of an automatic human urine detection system according to the present invention with reference to the accompanying drawings and embodiments.

Referring to fig. 1, an embodiment of the present invention provides an automatic human urine detection system, which includes a control module 100, a urine collecting module 200, a detection module 300, an output module 400, a cleaning module 500, and a storage module 600.

Wherein the control module 100 controls the automatic operation of the automation system to which the present invention relates, and comprises a command input unit. Wherein the urine collection module 200 is used for collecting urine to be detected; the detection module 300 comprises a detection probe seat, which is used for detecting the collected urine to be detected and obtaining a corresponding detection report according to the detection result; the output module 400 is configured to output the detection report; the cleaning module 500 is used for cleaning system components in the system, through which or stored the urine to be detected flows; the storage module 600 is used for storing the detection report, and a database may be disposed therein for storing the detection report.

When the instruction input unit of the control module 100 receives an external instruction, it notifies the urine collection module 200 to start and collect urine, and then instructs the detection probe holder of the detection module 300 to detect the collected urine, after the detection module 300 completes the detection, the detection result is output to the output module 400 to be output, and is also transmitted to the storage module 600 to be stored, and the cleaning module 500 cleans the used system components according to the instruction of the control module 100 for reuse. The output of the detection report of the detection module 300 may be performed by itself according to the setting inside the module, or may be performed according to the instruction of the control module 100, and specifically may be determined as needed, and is not limited, but is all within the scope of the present invention.

The modules will be described in detail with reference to the drawings.

The specific implementation of the control module may be in various forms, such as a single chip microcomputer form, a computer terminal form, an intelligent mobile terminal form, and the like.

In one embodiment, the control module 100, the output module 400 and the storage module 600 are implemented together by a smart terminal in combination with terminal application software used thereon. For example, the smart mobile terminal includes a smart phone, the instruction input unit is a terminal APP operating software, the display function included in the output module is implemented by a display screen of the smart phone, the printing function is implemented by a connected printer, and the storage module 600 is implemented by a storage card of the smart phone. In other embodiments, it may also be a computer terminal or an intelligent tablet terminal, which may be determined according to the needs and is not limited.

Wherein the urine collection module comprises a toilet stool, a urine collection assembly and a urine collection cup. Referring to fig. 2, in the present embodiment, the toilet stool is in the form of a toilet stool 101, wherein a toilet stool cavity 102 is disposed in the toilet stool 101, and a urine collecting channel 103 is disposed on an inner wall of the toilet stool cavity 102, wherein a urine collecting opening 104 is disposed in the urine collecting channel.

Referring to fig. 3 in combination with fig. 7, the urine collecting assembly includes a urine collector 110, and the urine collector 110 is provided with a urine collecting nozzle 111, a urine collecting piston 112, and an internal pipe, which communicates the urine collecting nozzle 111 and the urine collecting piston 112. Wherein the urine collection nozzle 111 is further provided with an upper cover 113, and the upper cover 113 is connected with an electromagnetic valve 114 through a linkage assembly.

Wherein the linkage assembly comprises a solenoid valve pull rod 115, a lever connecting piece 116 and a urinal lever 117; the electromagnetic valve 114 is energized to generate magnetic force to drive the electromagnetic valve pull rod 115 to pull towards the electromagnetic valve 114, the pull rod 115 rotates the urine collector lever 117 through the lever connecting piece 116, and then drives the urine collection piston 112 to rise so as to open the urine collection nozzle upper cover 113, so that urine to be detected from the urine collection opening 104 can enter the urine collection nozzle 111.

Further, the urine collecting piston 112 further comprises a piston outlet port 1120, which is communicated with the conduit in the urine collector 110, and the collected urine to be detected enters the urine collecting cup 2 (as shown in fig. 7) through the piston outlet port 1120 after passing through a urine collecting tube. The urinal 110 is also provided with a cleaning port 118 for allowing external clean water to be introduced when subsequent cleaning urine flows through the assembly.

Wherein, two sides of the urine collecting cup 2 (as shown in fig. 7) are provided with liquid level sensors, wherein when the urine to be detected in the urine collecting cup is collected to a predetermined liquid level, the liquid level sensors will sense and inform the electromagnetic valve 114 to perform a power-off operation. At this time, the electromagnetic valve pull rod 115 is pushed reversely to return to the original point under the action of the lost electromagnetic force, the pull rod 115 pushes the urine collector lever 117 to rotate back to the original position by linking with the lever connecting sheet 116, so that the urine collecting piston 112 descends, and the urine collecting nozzle upper cover 113 is retracted and closes the urine collecting nozzle 111.

Further, in different embodiments, the information sent by the liquid level sensor may also be sent to the control module, and then the control module controls the urine collection module to close, so that the solenoid valve is powered off.

Further, the detection module comprises a detection probe base 10 (shown in fig. 7), a detection cup 5 (shown in fig. 7) and a detection reagent delivery metering pump 4 (shown in fig. 7). Wherein the detection cup 5 is used for placing the urine to be detected and the detection reagent conveyed into the detection cup. The measuring reagent delivery metering pump is used for sucking the measuring reagent stored in the measuring reagent storage unit, and delivering the measuring reagent into the measuring cup 5 through a reagent distribution pipeline 7 (shown in FIG. 7) in a probe slide block 6 (shown in FIG. 7) positioned above the measuring cup 5. Wherein the test cup 5 and the urine collection cup 2 may be disposed on a test cup holder 17 (as shown in fig. 7).

Further, the urine collecting module further comprises a urine distribution metering pump 11 (shown in fig. 7), which is connected with the urine collecting cup 2 and conveys the urine to be detected in the urine collecting cup 2 to the detecting cup through a distribution pipeline thereof. The urine distribution metering pump can distribute urine of a plurality of detection cups through distribution pipelines thereof so as to implement a plurality of different urine detection items.

The detection probe seat comprises a main body, a sensor assembly and a data processing main board. Referring to fig. 4, 5 and 6 in combination with fig. 7 and 8, the main body includes a first connection plate 211, a second connection plate 212 and a third connection plate 213, the second connection plate 212 and the third connection plate 213 are symmetrically disposed at two ends of the first connection plate 211, a 214 through hole is disposed on the first connection plate 211, a groove 215 is disposed on an outer side surface of the first connection plate 211, and a probe holder glass 216 is disposed on inner side surfaces of the second connection plate 212 opposite to the third connection plate 213, respectively, wherein the probe holder glass 216 is made of a colorless transparent organic material to actually reflect a light intensity effect during a detection process.

The through hole 214 is connected with a driving screw 9 (shown in fig. 7), the through hole 214 is a threaded hole, the through hole 214 is in threaded sliding connection with the driving screw 9, the driving screw 9 is connected with a driving motor 8 (shown in fig. 7), the driving motor 8 drives the driving screw 9, and the driving screw 9 drives the detection probe holder 10 (shown in fig. 7) to slide along the length direction of the driving screw 9. The groove 215 is used for installing a positioning piece 240, the positioning piece 240 is positioning magnetic steel, and the positioning magnetic steel is used for positioning, so that the driving motor 8 and the driving screw 9 drive the detection probe seat 10 to be fixed when running to a specified position.

Wherein a first cover plate 231 and a second cover plate 232 are further disposed on the main body, wherein the first cover plate 231 is disposed on the outer side surface of the second connecting plate 12, the second cover plate 232 is disposed on the outer side surface of the third connecting plate 213, the first cover plate 231 and the second cover plate 232 are disposed in parallel, and the first cover plate 231 and the second cover plate 232 are used for fixing the liquid conveying pipeline.

Wherein the sensor assembly includes a sensor transmitter plate 221, a sensor receiver plate 222, a sensor moving adapter plate 223 and a probe moving adapter plate guard plate 224. The sensor emission plate 221 is disposed on an outer side surface of the second connection plate 212, and the sensor emission plate 221 is used for emitting light intensity; the sensor receiving plate 222 is disposed on an outer side surface of the third connecting plate 213, and the sensor receiving plate 222 is used for receiving light intensity; the sensor moving adapter plate 223 is disposed on the outer side surface of the first connecting plate 211, and the sensor moving adapter plate 223 is connected with the sensor transmitting plate 221 and the sensor receiving plate 222 through a wire harness; the probe moving adapter plate guard plate 224 is arranged on the sensor moving adapter plate 223 to protect the sensor moving adapter plate 223.

Further, the sensor emitting plate 221 and the sensor receiving plate 222 are respectively communicated with the probe seat glass 216, wherein the sensor emitting plate 221, the sensor receiving plate 222 and the probe seat glass 216 are all located at the same height as the detection cup. The content of a certain substance in the urine is obtained by utilizing the light intensity transmittance of the color of the detected urine after the reaction with the reagent, so that the purpose of detecting the liquid in the detection cup is realized.

The sensor mobile adapter plate 223 is configured to receive a detection instruction transmitted from the outside and transmit the detection instruction to the sensor transmitting plate 221, the sensor transmitting plate 221 transmits a light wave to urine to be detected, the light wave passing through the urine to be detected is received by the sensor receiving plate 222, and a received result is sent to the data processing main board 15 through the sensor mobile adapter plate 223 (as shown in fig. 8), and the data processing main board 15 processes the received data to obtain a detection result of the urine to be detected.

Wherein the washing module comprises a first washing pump 19 connected to a first washing pipe 18 (shown in fig. 7) whose washing spout corresponds to the detection cup and the urine collection cup. Wherein the detection cup and the urine collection cup are arranged on a detection cup support 17 (as shown in fig. 7), the cleaning module further comprises a cleaning motor 16 (as shown in fig. 7) which is connected with the detection cup support 17 through a rotating shaft, wherein the first cleaning pipeline is positioned below the detection cup support, and the cleaning nozzle comprises two nozzles which respectively correspond to the detection cup and the urine collection cup.

Further, the cleaning module further comprises a second washing pump 20 (shown in fig. 7) connected to a second washing pipe, wherein the second washing pipe is connected to a washing water inlet 118 of the urinal, and the washing water inlet 118 is communicated with a pipe arranged in the urinal. Wherein the cleaning module further comprises a sewage pump 21 (shown in fig. 7) for discharging the sewage remaining in the system after each cleaning using the system components is performed. And for the urine distribution metering pump, the urine distribution metering pump can automatically suck clean water to flush the inner part of the urine distribution metering pump and the distribution pipeline connected with the urine distribution metering pump according to instructions.

The automatic human urine detection system according to the present invention will be fully described with reference to fig. 7 and 8.

Please refer to fig. 7 and 8, the utility model relates to a when human urine automated inspection system is in operating condition, when needs carry out human urine and examine time measuring, open the APP software or the application operating software who moves on it on smart mobile phone, intelligent flat board or intelligent terminal's display device earlier and send the instruction that carries out the urine and detect, at this moment control module can instruct after receiving operating instruction the collection urine module is opened, human urine enters into afterwards in the collection urine ditch of toilet bowl.

When the urine collection module is opened, the electromagnetic valve 114 included in the urine collection module is electrified to generate magnetic force to drive the electromagnetic valve pull rod 115 to pull towards the electromagnetic valve 114, the pull rod 115 rotates the urine collection lever 117 through the lever connecting piece 116, and then drives the urine collection piston 112 to rise so as to open the urine collection nozzle upper cover 113 upwards, and at this time, the position of the urine collection nozzle 111 in an opened state is lower than that of the urine collection nozzle 104.

Further, as shown in fig. 2 and 3, since the design of the urine collection groove 103 is preferably U-shaped, and the position of the urine collection opening 104 is at the lowest position of the urine collection groove 103, the urine will automatically gather to the position of the urine collection opening 104 through the urine collection groove 103 and then enter the urine collection mouth 111, and flow into the urine collection cup 2 through the internal conduit of the urine collection device via the urine collection piston outlet 1120.

When the urine is collected to a preset liquid level, the liquid level sensors arranged at two sides of the urine collection cup 2 sense the liquid level, and then inform the electromagnetic valve 114 of power failure, the electromagnetic valve pull rod 115 is reversely pushed to return to the original point after the electromagnetic force is lost, the pull rod 115 pushes the urine collection lever 117 to rotate to return to the original position through the lever connecting sheet 116, so that the urine collection piston 112 descends, the urine collection nozzle upper cover 113 is retracted to further seal the urine collection nozzle 111, and subsequent urine cannot enter the urine collection nozzle 111 and flows to the urinal outlet through the flow guide outlet of the toilet bowl to be discharged.

Subsequently, according to the instruction of the control module, the introduced external clear water will flush the urine collection trench 103 and the urine collection port 104, and simultaneously, the introduced internal clear water of the cleaning module will automatically flush the components related to the collected urine flowing through the urine collector through the urine collection module flushing water inlet 118 for the next use. Therefore, the whole collection process of the human urine to be detected is completed automatically, so that bacterial pollution is avoided, and pollution among different human urine is avoided.

Further, the reagent delivery metering pump 3 in the detection module sucks the reagent in the reagent storage module 4, and dispenses the reagent into the corresponding detection cup 5 through the reagent dispensing pipeline 7 in the probe slide 6 positioned above the detection cup 5. The driving motor 8 drives the driving screw rod 9 to further drive the detection probe seat 10 connected with the driving screw rod to slide above the detection cup 5, and the positioning magnetic steel 240 on the detection probe seat 10 is positioned in the movement process, so that the liquid conveying and the liquid detection are both in correct positions.

At this time, urine in the urine collecting cup 2 is transmitted to the urine dripping port in the detection probe seat 10 through the water outlet pipe of the urine distribution metering pump 11 and is distributed to the detection cup 5, the detection probe seat 10 starts detection, a sensor moving adapter plate 223 included in the urine collecting cup transfers a detection instruction to the sensor emitting plate 221, the sensor emitting plate 221 emits light waves, the light waves penetrating through liquid are received by the sensor receiving plate 222, the result is sent to the data processing main board 15 through the sensor moving adapter plate 223, and the detection result obtained by processing of the data processing main board 15 is sent to the display terminal to be displayed and can also be sent to printing equipment to be printed.

After the detection is finished, components related to flowing and storing of urine to be detected in the system are cleaned, specifically, the cleaning motor 16 drives the rotating shaft to drive the detection cup support 17 and the detection cup 5 and the urine collection cup 2 arranged on the detection cup support to turn over for 180 degrees, as the first cleaning pipeline 18 is positioned right below the detection cup support 17 and is provided with cleaning spray holes facing the detection cup 5 and the urine collection cup 2, one outlet of the first washing pump 19 is connected with the first cleaning pipeline 18, and the detection cup 5 and the urine collection cup 2 are further washed; the urine distribution metering pump 11 automatically absorbs clean water to flush the internal part of the urine distribution metering pump and the connected urine distribution pipeline; as described in the urine collection process of the urine collection module, the outlet of the second washing pump 20 is connected to the washing port 118 of the urine collection module to wash the urine flow passage inside the urine collection module; the sewage pump 21 empties the used sewage after cleaning to wait for the next detection.

The utility model relates to an automatic detecting system of human urine, its automatic collection and subsequent automated inspection in an organic whole that collects human urine, the effectual process of simplifying whole urine examination, and operation process hommization, user experience is good.

Further, the utility model relates to an automatic detecting system of human urine can also combine mobile terminal to use, for example, the cell-phone for its convenient operation, the range of application is wide.

The technical scope of the present invention is not limited to the content in the above description, and those skilled in the art can make various modifications and alterations to the above embodiments without departing from the technical spirit of the present invention, and these modifications and alterations should fall within the scope of the present invention.

Claims (10)

1. An automatic detection system for human urine; the urine collection device is characterized by comprising a control module, a urine collection module, a detection module, an output module and a cleaning module;

the control module controls the operation of the whole system and comprises an instruction input unit; the urine collecting module is used for collecting urine to be detected; the detection module comprises a detection probe seat used for detecting the collected urine to be detected and obtaining a corresponding detection report according to a detection result; the output module is used for outputting the detection report, and the cleaning module is used for cleaning system components in the system, through which the urine to be detected flows or is stored;

when the instruction input unit of the control module receives an external instruction, the instruction input unit informs the urine collection module to start and collect urine, the detection probe seat of the detection module detects the collected urine and outputs a detection result to the output module for output, and the cleaning module cleans used system components according to the instruction of the control module for reuse.

2. An automated human urine detection system according to claim 1; the urine collection module comprises a toilet, a urine collection assembly and a urine collection cup; a chamber pot is arranged in the toilet bowl, a urine collecting ditch is arranged on the inner wall of the chamber pot, and a urine collecting port is arranged in the urine collecting ditch; the urine collection assembly comprises a urine collection device, a pipeline and a urine collection mouth are arranged in the urine collection device, and the pipeline is communicated with the urine collection mouth and the urine collection cup; wherein the urine collecting nozzle is also provided with an upper cover which is connected with an electromagnetic valve through a linkage component;

after the electromagnetic valve of the urine collection module is electrified, the linkage assembly can be driven to open the upper cover of the urine collection nozzle, so that urine to be detected can enter the urine collection nozzle through the urine collection opening of the urine collection ditch and then flow through the pipeline in the urine collection device to enter the urine collection cup.

3. An automated human urine detection system according to claim 2; the urine collector is characterized in that the linkage assembly comprises an electromagnetic valve pull rod, a lever connecting piece and a urine collector lever, and a urine collecting piston is arranged in the urine collector; the electromagnetic valve is electrified to generate magnetic force to drive the electromagnetic valve pull rod to pull towards the direction of the electromagnetic valve, and the pull rod enables the urine collector lever to rotate through the lever connecting piece, so that the urine collecting piston is driven to rise, and the upper cover of the urine collecting nozzle is opened.

4. An automated human urine detection system according to claim 3; the urine collection cup is characterized in that a liquid level sensor is arranged on one side of the urine collection cup; when the urine to be detected in the urine collection cup is collected to a preset liquid level, the liquid level sensor senses the urine and informs the electromagnetic valve to perform power-off operation.

5. An automated human urine detection system according to claim 4; the urine collecting piston is characterized by further comprising a piston leading-out port which is communicated with a pipeline in the urine collector, and the collected urine to be detected enters the urine collecting cup through the piston leading-out port after passing through a urine collecting pipe.

6. An automated human urine detection system according to claim 2; the detection probe seat is characterized by comprising a sensor assembly and a data processing main board, wherein the sensor assembly comprises a sensor moving adapter plate, a sensor transmitting plate and a sensor receiving plate;

the sensor mobile adapter plate is used for receiving an externally transmitted detection instruction and conveying the detection instruction to the sensor transmitting plate, the sensor transmitting plate transmits light waves to urine to be detected, the light waves penetrating through the urine to be detected are received by the sensor receiving plate, receiving results are sent to the data processing main board through the sensor mobile adapter plate, and the data processing main board obtains detection results of the urine to be detected through data processing.

7. An automated human urine detection system according to claim 6; the device is characterized in that the detection module also comprises a detection cup used for placing urine to be detected and a detection reagent conveyed into the detection cup;

the detection module also comprises a detection reagent conveying metering pump which sucks the detection reagent stored in the detection reagent storage unit and conveys the detection reagent into the detection cup through a reagent distribution pipeline in the probe sliding block positioned above the detection cup;

the sensor transmitting plate and the sensor receiving plate are respectively communicated with a probe seat glass, the sensor transmitting plate, the sensor receiving plate and the probe seat glass are all positioned at the same height with the detection cup, and the purpose of detecting the liquid in the detection cup is achieved by utilizing the light intensity transmittance of the color of the urine to be detected after the urine to be detected reacts with the added detection reagent.

8. An automated human urine detection system according to claim 7; the washing module comprises a first washing pump which is connected with a first washing pipeline, and a washing nozzle of the first washing pipeline corresponds to the detection cup and the urine collection cup;

the cleaning module further comprises a cleaning motor which is connected with the detection cup bracket through a rotating shaft, wherein the first cleaning pipeline is positioned below the detection cup bracket, and the cleaning nozzle comprises two nozzles which respectively correspond to the detection cup and the urine collection cup;

the detection cup support is turned over by the rotation of the cleaning motor to pour waste liquid in the detection cup and the urine collection cup, and cleaning liquid is sprayed out through the cleaning nozzle to wash the detection cup and the urine collection cup.

9. An automated human urine detection system according to claim 1; the device is characterized in that the output module comprises a display screen and/or a printer, the control module is further connected with a storage module, and a database is arranged in the storage module and used for storing detection reports.

10. An automated human urine detection system according to claim 1; the control module and the output module are combined together to be realized by an intelligent terminal.

Images