CN210572339U - Intelligent electronic ovulation detector capable of automatically detecting start of measurement - Google Patents

Abstract

The utility model provides an intelligent electronic ovulation detector for automatically detecting and starting to measure actions, which comprises a shell, a main control board, a light guide device and a test paper rod, wherein the main control board, the light guide device and the test paper rod are arranged in the shell; the main control board is provided with a processor, a memory and a trigger switch, the processor is connected with the memory and the trigger switch in a communication mode, and the trigger switch is used for starting measurement when the detector is inserted into the test paper stick. When urine sample enters the test paper rod window, the absorption amount of the test paper to light is suddenly increased, so that the residual light collected by the sensor is suddenly reduced, and therefore, the urine sample is detected to enter the window through the sudden drop of the light collected by the sensor, the measurement action is triggered to start, and the urine sample enters a timing state.

Description

Intelligent electronic ovulation detector capable of automatically detecting start of measurement

Technical Field

The utility model relates to an ovulation detects technical field, in particular to automatic detect and begin to measure intelligent electron ovulation detector of action.

Background

Luteinizing hormone is a glycoprotein gonadotropin secreted by adenohypophysis cells, and promotes the conversion of cholesterol into sex hormones in gonadal cells. In women, luteinizing hormone is involved in ovulation induction by follicle stimulating hormone, and in the formation and secretion of estrogen and progestin. The release peak of luteinizing hormone is closely related to ovarian ovulation, and once the peak appears, the peak indicates 24-36 hours of ovarian ovulation. Currently, the methods for detecting luteinizing hormone mainly comprise a radioimmunoassay, a cervical mucus observation method, a basal body temperature detection method, a vaginal B-ultrasonic imaging method, an ovulation test paper detection method and the like.

The electronic detection device for detecting the physiological cycle of the female in the prior art mostly adopts the electrical characteristic measurement to judge the ovulation time of the female according to the change rule of saliva and cervical mucosal electrolyte of the female in the physiological cycle. In the test process, a human body is in direct contact with a test piece of the test device, so that the safety and the sanitation are not sufficient. There are also portable ovulation monitors that detect luteinizing hormone in urine to determine the time of ovulation.

However, in use of the ovulation monitor, urine reaches a designated position on the membrane surface of the strip, at which point the measurement is initiated. There is a fixed time period from the completion of urine collection to the start of reading, and the result changes with time. In the existing scheme, when a user starts to use an instrument or takes urine, a manual key triggers a device to start timing, and a detection result is read after a fixed period of time. The manual operation of the user easily causes inaccuracy of the fixed time from the completion of urine collection to the start of reading the result, which causes errors and directly affects the test result. In addition, the ovulation detector in the prior art has the problem of inconvenient use, and a user forgets to press a button manually, so that the situation that the test has no result can occur.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems in the prior art, the utility model aims to provide an intelligent electronic ovulation detector for automatically detecting the beginning of measurement, which triggers the event of starting measurement by a device through the change of a sensor collecting test paper, accurately records the starting time of the test, and reduces the error caused by inaccurate time when reading the result; when the sensor detects the sample loading, the sensor prompts to stop the sample loading at once to ensure that the sample loading quantities of different users are consistent, avoid the influence of different sample loading quantities on the result, and avoid the complicated operation of manual triggering of the user.

In order to solve the above problems, the utility model adopts the following technical proposal.

The utility model provides an automatic detect intelligent electron ovulation detector that begins to measure action, includes the casing and arranges the test paper stick that inside main control board, leaded light equipment and the cooperation casing of casing used in, in the test paper stick was arranged in to the test paper, the leaded light equipment included photosensitive sensor, its characterized in that: the main control board is provided with a processor, the photosensitive sensor is connected with the main control board in a communication mode, and when the photosensitive sensor detects the sudden drop of the lighting value, a signal is sent to the processor to start detection.

Furthermore, a reaction area with a fixed length is arranged on the reaction surface of the test paper on the test paper.

Furthermore, a fiber membrane is designed on the test paper, a reaction line is arranged on the fiber membrane, and the length from the reaction line to the urine inlet edge of the test paper is fixed.

Further, the test paper includes the sample pad fibre membrane and absorbent paper, the first end of sample pad with fibre membrane second end press mold is connected, the first end of fibre membrane with absorbent paper second end press mold is connected, be equipped with C line and T line on the fibre membrane, form reaction zone between sample pad second end and the T line.

Further, the sound generating device is communicatively connected to the processor, and the trigger switch.

Further, the total length of the test strip is controlled to be about 100mm, wherein the size of the reaction area is controlled to be about 60 mm.

Furthermore, a first light through hole, a second light through hole, an optical signal emitter arranged in the first light through hole and the photosensitive sensor arranged in the second light through hole are arranged in the light guide device, the optical signal emitter and the photosensitive sensor are communicatively connected to the processor, and the first light through hole and the second light through hole are both communicated with the test paper detection cavity.

Further, the light guide equipment forms a limiting piece, and the test paper rod slides in the test paper detection cavity and is limited by the limiting piece; the periphery of the detection position is provided with a fixing mechanism which is implemented as a cover, and the cover fills the gap between the test paper stick and the light guide device.

Furthermore, the main control board further comprises a display device and a Bluetooth emitter, the display device and the Bluetooth emitter are connected with the processor in a communication mode, and the processor transmits signals outwards through the Bluetooth emitter.

Further, the light guide device comprises a light isolation plate arranged between the optical signal emitter and the photosensitive sensor, the side edge of the light isolation plate abuts against the optical signal emitter and the photosensitive sensor, the bottom side of the light isolation plate abuts against the position of the test paper detection cavity, and the light isolation plate is made of a light shielding material.

Drawings

Fig. 1 is a schematic diagram of an intelligent electronic ovulation monitor for automatically detecting the start of a measurement operation according to an embodiment of the present invention;

fig. 2 is a schematic diagram of an internal module of an intelligent electronic ovulation monitor for automatically detecting the start of a measurement operation according to an embodiment of the present invention;

fig. 3 is a schematic diagram of a test paper of an intelligent electronic ovulation monitor for automatically detecting the start of a measurement operation according to an embodiment of the present invention;

fig. 4 is a schematic diagram of a light guiding structure of an intelligent electronic ovulation monitor for automatically detecting the start of a measurement operation according to an embodiment of the present invention;

fig. 5 is an automatic detection schematic diagram of an intelligent electronic ovulation detector for automatically detecting the start of a measurement operation according to an embodiment of the present invention.

The reference numbers in the figures illustrate:

the device comprises a shell 1, a main control board 20, a processor 21, a memory 22, a trigger switch 23, a light guide device 30, an optical signal emitter 31, a photosensitive sensor 32, a light isolating board 33, a first light through hole 34, a second light through hole 35, a test paper stick 40, a sample pad 41, a fiber membrane 42, absorbent paper 43, a display device 5 and a cover 6.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art all belong to the protection scope of the present invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purposes of limitation.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Exemplary embodiments according to the present invention will be described below with reference to the accompanying drawings.

Referring to fig. 1-5, an intelligent electronic ovulation detector for automatically detecting the start of a measurement operation includes a housing 1, a main control board 20 disposed inside the housing 1, a light guide device 30, and a test paper rod 40 used in conjunction with the housing 1, wherein test paper is disposed in the test paper rod 40, the light guide device 30 includes a photosensitive sensor 32, and is characterized in that: the main control board 20 is provided with a processor 21, the photosensitive sensor 32 is communicatively connected to the main control board 20, and when the photosensitive sensor 32 detects a sudden drop in the lighting value, a signal is sent to the processor 21 to start the detection.

Specifically, as shown in fig. 5, the horizontal axis represents time, and the vertical axis represents the acquired value of the photosensor 32. The test paper is stretched into the test paper detection cavity to be detected, when the urine sample does not enter the test paper rod window, the collection value of the photosensitive sensor 32 is at the peak value, when the urine sample enters the test paper rod window, the absorption amount of the test paper to light is suddenly increased, so that the residual light collected by the photosensitive sensor 32 is suddenly reduced, namely the collection value in the figure is suddenly reduced. Therefore, the light quantity collected by the light sensor 32 of the light guide device 30 is suddenly reduced to detect the urine sample entering the window, so as to trigger the start of the measurement operation and enter the timing state.

Furthermore, a reaction area with a fixed length is arranged on the reaction surface of the test paper on the test paper.

Wherein, the fiber membrane 42 is designed on the test paper, the fiber membrane 42 is provided with a reaction line, and the length from the reaction line to the urine inlet edge of the test paper is fixed.

In addition, the test paper includes a sample pad 41, a fiber membrane 42 and a water absorption paper 43, a first end of the sample pad 41 is connected with a second end of the fiber membrane 42 through a press film, a first end of the fiber membrane 42 is connected with a second end of the water absorption paper 43 through a press film, a C line and a T line are arranged on the fiber membrane 42, in the embodiment, the C line is arranged at a position close to the first end of the fiber membrane, the T line is arranged at a position close to the second end of the fiber membrane, and a reaction area is formed between the second end of the sample pad 41 and the.

Also included is a sound emitting device communicatively connected to the processor 21, as well as a trigger switch 23.

The master control board model is "BONGMI OV", and the photosensitive sensor can transmit signal is its function of self-carrying, the utility model discloses select the photosensitive sensor of PD15-22C/TR8 model, be prior art about its introduction, do not redundantly explain here again.

In this embodiment, when the test paper is inserted, an elastic structure on the light guide structure is elastically deformed to press the trigger switch 23 for triggering, and at this time, the start of measurement is not performed, but the device is told, and the user inserts the test paper into the device. The sound production device is a buzzer, when the photosensitive sensor 32 detects the sample loading, the buzzer buzzes, and the LED status light accelerates the flashing frequency to prompt the user to stop the sample loading.

Further, the total length of the test strip was controlled to be about 100mm, and the size of the reaction region was controlled to be about 60 mm.

Specifically, as shown in FIG. 3, since the length from the sample application end to the reaction region is fixed, the amount of the urine sample is the same when the urine sample is applied to the reaction region, thereby ensuring the consistency of the sample application amount.

The light guide device 30 is internally provided with a first light through hole 34, a second light through hole 35, a light signal emitter 31 arranged in the first light through hole 34 and a photosensitive sensor 32 arranged in the second light through hole 35, the light signal emitter 31 and the photosensitive sensor 32 are communicatively connected to the processor 21, and the first light through hole 34 and the second light through hole 35 are both communicated with the test paper detection cavity.

Specifically, as shown in fig. 4, the optical signal emitter 31 is an LED light emitting element, and light emitted from the LED light emitting element reaching the test paper detection cavity may be reflected to the photosensitive sensor 32 for absorption.

Further, the light guide device 30 forms a limiting member, and the test paper rod 40 slides in the test paper detection cavity and is limited by the limiting member; in some embodiments, the detection site is peripherally provided with a fixing mechanism embodied as a cover 6, the cover 6 filling the gap between the test paper stick 40 and the light guide 30. For example, the fixing mechanism is implemented as a fixing arm and a base disposed at both sides of the test paper detection position, and is used to fix the test paper disposed on the test paper detection position.

It should be mentioned that the main control board 20 further includes a display device 5 and a bluetooth transmitter, the display device 5 and the bluetooth transmitter are communicatively connected to the processor 21, and the processor 21 transmits signals to the outside through the bluetooth transmitter.

In the embodiment, the upper part of the housing 1 is provided with a display area, which is designed as a through hole, and the display device 5 is arranged in the display area.

Further, the light guide device 30 includes a light shielding plate 33 disposed between the optical signal emitter 31 and the photosensitive sensor 32, a side of the light shielding plate 33 abuts against the optical signal emitter 31 and the photosensitive sensor 32, a bottom side of the light shielding plate 33 abuts against the position of the test paper detection cavity, and the light shielding plate 33 is made of a light shielding material.

In the detection process, after the test paper rod is inserted, the photosensitive sensor detects the sudden drop of the light absorption amount, and the equipment is triggered to perform the test. And when the set sample injection amount is detected, reminding a user to stop sample injection.

The present invention is not limited to the above-mentioned preferred embodiments, and any other products in various forms can be obtained by the teaching of the present invention, but any changes in the shape or structure thereof, which have the same or similar technical solutions as the present invention, fall within the protection scope of the present invention.

Claims (10)

1. The utility model provides an automatic detect intelligent electronic ovulation detector that begins to measure action, includes casing (1) and arranges main control panel (20), leaded light equipment (30) and the test paper stick (40) that cooperation casing (1) used in casing (1) inside in, in test paper stick (40) was arranged in to the test paper, leaded light equipment (30) included photosensitive sensor (32), its characterized in that: the main control board (20) is provided with a processor (21), the photosensitive sensor (32) is connected with the main control board (20) in a communication mode, and when the photosensitive sensor (32) detects the sudden drop of the lighting value, a signal is sent to the processor (21) to start detection.

2. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: the reaction surface of the test paper on the test paper is provided with a reaction area with a fixed length.

3. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: the test paper is provided with a fiber membrane (42), a reaction line is arranged on the fiber membrane (42), and the length from the reaction line to the urine inlet edge of the test paper is fixed.

4. An intelligent electronic ovulation monitor as claimed in claim 3, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement movement, and further comprises: the test paper includes sample pad (41), fibrous membrane (42) and absorbent paper (43), and the first end of sample pad (41) is held the press mold with fibrous membrane (42) second and is connected, and fibrous membrane (42) first end is held the press mold with absorbent paper (43) second and is connected, is equipped with C line and T line on fibrous membrane (42), forms reaction area between sample pad (41) second end and the T line.

5. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: also included is a sound emitting device communicatively connected to the processor (21), and a trigger switch (23).

6. An intelligent electronic ovulation monitor as claimed in any one of claims 1 to 5, wherein: the total length of the test paper is controlled to be about 100mm, and the size of the reaction area is controlled to be about 60 mm.

7. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: light guide equipment (30) are built-in to be equipped with first logical unthreaded hole (34), second logical unthreaded hole (35), place light signal transmitter (31) in first logical unthreaded hole (34) in and place photosensitive sensor (32) in second logical unthreaded hole (35) in, light signal transmitter (31) and photosensitive sensor (32) are connected in treater (21) communicatingly, and first logical unthreaded hole (34) and second logical unthreaded hole (35) all communicate with each other with the test paper detection chamber.

8. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: the light guide device (30) forms a limiting piece, and the test paper rod (40) slides in the test paper detection cavity and is limited by the limiting piece; the periphery of the detection position is provided with a fixing mechanism which is implemented as a cover (6), and the cover (6) fills the gap between the test paper rod (40) and the light guide device (30).

9. The intelligent electronic ovulation monitor as claimed in claim 7, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: the main control board (20) further comprises a display device (5) and a Bluetooth emitter, the display device (5) and the Bluetooth emitter are connected with the processor (21) in a communication mode, and the processor (21) transmits signals outwards through the Bluetooth emitter.

10. The intelligent electronic ovulation monitor as claimed in claim 1, wherein said intelligent electronic ovulation monitor is adapted to automatically detect the start of a measurement operation, and further comprises: the light guide device (30) comprises a light isolation plate (33) arranged between the optical signal emitter (31) and the photosensitive sensor (32), the side edge of the light isolation plate (33) abuts against the optical signal emitter (31) and the photosensitive sensor (32), the bottom side of the light isolation plate abuts against the position of the test paper detection cavity, and the light isolation plate (33) is prepared from a light-shielding material.

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