CN112119922A

CN112119922A - Pet nest and monitoring method of pet physiological data

Info

Publication number: CN112119922A
Application number: CN202011118566.6A
Authority: CN
Inventors: 沈雪丹
Original assignee: Senqiang Hangzhou Technology Co ltd
Current assignee: Senqiang Hangzhou Technology Co ltd
Priority date: 2020-10-19
Filing date: 2020-10-19
Publication date: 2020-12-25

Abstract

The invention relates to a pet nest and a monitoring method of pet physiological data. The socket body is provided with a concave part. The concave part is used for the pet to lie on stomach. The plurality of temperature sensors are provided with temperature value acquisition ends and temperature value output ends. The temperature acquisition ends of the plurality of temperature sensors are arranged on the bottom surface of the concave part. The temperature of cat different positions can be gathered to a plurality of temperature sensor, and the treater can obtain the target temperature value according to a plurality of temperature sensor, and data output end can output the target temperature value. The processor can acquire a target temperature value according to the temperature sensors, and the body temperature of the pet can be accurately measured.

Description

Pet nest and monitoring method of pet physiological data

Technical Field

The invention relates to the field of pet products, in particular to a method for monitoring physiological data of a pet nest and a pet.

Background

At present, physiological data of a household pet comprises temperature data and weight data, in the monitoring of pet temperature data, the temperature of the pet is generally measured by a fixed temperature measuring instrument in the prior art, and the accuracy of the temperature measuring instrument for measuring the body temperature of the pet is low because the temperature of different parts of the pet is different and the pet moves randomly in the temperature measuring process to cause the position of the pet to be unfixed.

Disclosure of Invention

The invention aims to provide a method for monitoring physiological data of a pet house and a pet, which improves the accuracy of monitoring the physiological data of the pet.

In order to realize the purpose, the technical scheme is as follows: a pet nest comprises a nest body, a plurality of temperature sensors and a processor. The socket body has a recess. The concave part is used for the pet to lie on stomach.

The temperature sensors are provided with a temperature value acquisition end and a temperature value output end. The temperature acquisition ends of the plurality of temperature sensors are arranged on the bottom surface of the concave part, and the temperature value output end can output the temperature value acquired by the temperature acquisition ends.

A processor having a data input and a data output. The data input end is connected with the temperature value output end, and the data input end can acquire a plurality of temperature values acquired by a plurality of temperature sensors. The processor can obtain a target temperature value according to the plurality of temperature sensors, and the data output end can output the target temperature value.

Further, the socket body has an inner cavity. The bottom plate of the depressed part is provided with a plurality of through holes. The through holes are arranged in an array. The through hole is communicated with the inner cavity. The temperature sensors are arranged in the inner cavity, the temperature acquisition ends are positioned in the through holes, and the temperature acquisition ends of the temperature sensors protrude out of the bottom surface of the concave part.

Further, the socket body includes: the upper nest body is provided with a concave part, the peripheral wall of the upper nest body is provided with a notch, and the upper edge of the upper nest body is provided with an outward flange. The lower nest body is provided with a lower concave part, and the upper edge of the lower nest body is connected with the outward flanging of the upper nest body. An inner cavity is formed between the inner peripheral wall of the lower nest body and the outer peripheral wall of the upper nest body.

The pet nest further comprises a plurality of weighing sensors, the weighing sensors are arranged on the bottom surface of the lower nest body, each weighing sensor is provided with a weight output end, and the weight output ends are connected with the data input end of the processor.

Wherein, a plurality of weight value that a plurality of weighing sensor gathered can be acquireed to the data input of treater. The processor can obtain a target weight value according to a plurality of weight values, and the processor can output the target weight value.

Furthermore, the pet nest also comprises a heat insulation plate which is arranged on the back surface of the bottom plate. A heat shield is positioned within the interior cavity. The heat insulation plate is provided with a plurality of avoiding holes. The avoiding holes correspond to the through holes one by one.

The through hole comprises a middle through hole and a plurality of outer ring through holes, and the middle through hole is arranged in the middle of the bottom plate. The outer ring through holes are uniformly arranged on the bottom plate at intervals around the middle through hole. Six outer ring through holes are arranged around the middle through hole.

Further, the back of the bottom plate is connected with or integrally formed with a plurality of hollow cylinders. The hollow cylinder is correspondingly communicated with the through hole. The temperature collector is a thermistor. The thermistor is inserted in the hollow cylinder. One end of the thermistor is positioned in the through hole.

Further, the pet house also comprises a memory, a WIFI module and a 2G module, wherein the memory is provided with a data input end and a data output end. The data input end of the memory is connected with the data output end of the processor, and the memory can store a target temperature value and a target weight value.

The WIFI module can establish data transmission connection with external equipment. The WIFI module can send the target temperature value and the target weight value cached in the memory to the external device through the server.

The 2G module is capable of establishing a data transmission connection with an external device. The 2G module can send the target temperature value and the target weight value cached in the memory to the external equipment through the server.

The processor judges whether the network state of the WIFI module is abnormal or not. And if so, uploading the target temperature mean value and the target weight value to the external equipment through the 2G module within the set time value.

The processor judges whether the network states of the WIFI module and the 2G module are both abnormal. If so, temporarily storing the target temperature value and the target weight value in a memory, and packaging and uploading the target temperature value and the target weight value to the server and clearing local data stored in the memory under the condition that the WIFI module or the 2G network can be normally connected with external equipment through the server.

A method for monitoring physiological data of a pet in the pet nest comprises the following steps:

the processor obtains temperature values input by a plurality of temperature sensors. And acquiring a first temperature value, a second temperature value and a third temperature value of which the temperature values are from high to low.

And judging whether the temperature difference value of any two of the first temperature value, the second temperature value and the third temperature value is between 0 and 0.5 ℃.

If yes, judging whether the temperature difference value of the first temperature value and the second temperature value is between 0 and 0.2 ℃.

If so, acquiring the temperature mean value of the first temperature value and the second temperature value, and taking the temperature mean value as a target temperature value.

Further, the monitoring method of the physiological data of the pet comprises the following steps:

the processor acquires a weight value acquired by the weighing sensor. A set number of weight values are obtained in a sliding window manner.

The processor acquires a latest weight value, and the sliding window discards an initially acquired weight value.

The processor calculates a standard deviation of the weight values for the set amount in the sliding window. And judging whether the standard deviation is less than 0.2.

If so, acquiring a weight average value of the weight values in the sliding window, and taking the weight average value as a target weight value.

Compared with the prior art, the invention has the technical effects that: a plurality of temperature collectors are arranged on the bottom surface of the concave part. The nest of lying prone of cat is in the bottom surface of depressed part like this, and the temperature of cat different positions can be gathered to a plurality of temperature sensor, and the treater can obtain the target temperature value according to a plurality of temperature sensor, ensures to measure the body temperature of cat accurately.

Drawings

Fig. 1 is a perspective view of a pet nest of the present invention.

Fig. 2 is a cross-sectional view of the pet nest of the present invention.

Fig. 3 is an exploded view of the pet nest of the present invention.

Fig. 4 is an exploded view of the pet nest of the present invention.

Fig. 5 is a schematic diagram of a pet physiological data transmission process according to the present invention.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

As shown in fig. 1, a first embodiment of the present invention provides a pet nest comprising: a nest 10, a plurality of temperature sensors 20 and a processor. The socket body 10 has a recess 11. The concave part 11 is used for the pet to lie on the stomach.

And a plurality of temperature sensors 20 having a temperature value collecting terminal and a temperature value output terminal. The temperature acquisition ends of the plurality of temperature sensors 20 are arranged on the bottom surface of the concave part 11, and the temperature value output end can output the temperature value acquired by the temperature acquisition ends.

A processor having a data input and a data output. The data input end is connected with the temperature value output end, and the data input end can acquire a plurality of temperature values that a plurality of temperature sensor 20 gathered. The processor can obtain a target temperature value according to the plurality of temperature sensors 20, and the data output end can output the target temperature value.

When the pet is at rest, the pet nest of lying prone is in depressed part 11, because the temperature of the different positions of pet is different, for example the pet is the cat, the inboard temperature of front leg of cat is less than abdominal temperature, the inboard temperature of back leg of cat is less than the abdominal temperature, because the posture of cat is different, and the inboard temperature of back leg is the standard temperature moreover many times, therefore the body temperature of cat is difficult to measure.

The invention arranges a plurality of temperature collectors 20 on the bottom surface of the concave part 11. The nest of lying prone of cat is in the bottom surface of depressed part 11 like this, and the temperature of cat different positions can be gathered to a plurality of temperature sensor 20, and the treater can obtain the target temperature value according to a plurality of temperature sensor 20, ensures to measure the body temperature of cat accurately.

As shown in fig. 2, the socket body 10 has an inner cavity 13. The bottom plate 12 of the concave part 11 is provided with a plurality of through holes 14. The plurality of through holes 14 are arranged in an array. The through hole 14 communicates with the inner cavity 13.

A plurality of temperature sensor 20 sets up in inner chamber 13, and the temperature acquisition end is located through-hole 14, and the temperature acquisition end protrusion of temperature sensor 20 is in the bottom surface of depressed part 11.

Specifically, through set up through-hole 14 on bottom plate 12, the temperature acquisition end protrusion in the bottom surface of depressed part 11 of temperature sensor 20 who sets up in inner chamber 13 ensures that the temperature acquisition end can paste mutually with the body surface of cat, and then guarantees to measure the temperature of pasting department with the temperature acquisition end accurately.

Specifically, the through hole 14 includes a middle through hole and a plurality of outer ring through holes, and the middle through hole is opened in the middle of the bottom plate 12. A plurality of outer ring through holes are evenly spaced around the middle through hole and are arranged on the bottom plate 12. Six outer ring through holes are arranged around the middle through hole.

Through the aforesaid is the through-hole 14 that the array set up, temperature collector's temperature acquisition end sets up and is the array in through-hole 14 back equally, and no matter how the position of nest in 11 bottom surfaces of depressed part is lied prone to the cat like this, and the temperature homoenergetic of the front leg inboard, belly and the back leg inboard of cat can be gathered, further guarantees to measure the body temperature of cat accurately.

As shown in fig. 3 and 4, the socket body 10 includes an upper socket body 15 and a lower socket body 16.

The upper nest body 15 is provided with a concave part 11, the peripheral wall of the upper nest body 15 is provided with a gap 152, and a cat can enter and exit the concave part 11 through the gap arranged on the peripheral wall of the upper nest body 15.

The upper edge of the upper socket body 15 is provided with a flanging 151. The lower socket 16 has a lower recess 161 and the upper edge of the lower socket 16 is connected to the flange 151 of the upper socket 15. An inner cavity 13 is formed between the inner peripheral wall of the lower socket body 16 and the outer peripheral wall of the upper socket body 15.

The upper edge of the lower socket body 16 is connected with the flanging 151 of the upper socket body 15, so that the components such as the temperature sensor 20 and the circuit board 50 can be accommodated, the flanging 151 of the upper socket body 15 is directly integrated with the upper edge of the lower socket body 16 in a press fitting manner, the structure is simple, and the assembly is convenient.

The pet nest also includes a number of load cells 40. A plurality of load cells 40 are disposed on the bottom surface of the lower socket body 16, the load cells 40 having a weight output connected to the data input of the processor.

Wherein, the data input of processor can acquire a plurality of weight values that a plurality of weighing sensor 40 gathered. The processor can obtain a target weight value according to a plurality of weight values, and the processor can output the target weight value.

Weighing sensor 40 can adopt the scheme of two foil gauges and two resistances, reduces two foil gauges, reduces the installation and structural design degree of difficulty, and the mark degree of difficulty is lower, can effectively reduce cost, reduces and walks the line and assembles the degree of difficulty.

The pet litter also includes a heat shield 30, the heat shield 30 being disposed on the back of the base 12. An insulating panel 30 is positioned within the interior cavity 13. The heat insulation plate 30 is provided with a plurality of avoiding holes 31. The avoiding holes 31 correspond to the through holes 14 one to one.

The heat insulation plate 30 can be a vacuum plate, and the heat insulation plate 30 can play a role in isolating the heat of the pet, so that on one hand, the temperature of the contact part of the bottom plate 12 and the pet is rapid, and the body temperature collection speed of the pet is improved; on the other hand, the influence of the measurement precision of the weighing sensor 40 due to the temperature rise is avoided, and the measurement precision of the weighing sensor is improved.

The back of the base plate 12 is connected to or integrally formed with a plurality of hollow cylinders 121. The hollow cylinder 121 is correspondingly communicated with the through hole 14. Temperature harvester 20 is a thermistor. The thermistor is inserted into the hollow cylinder 121. One end of the thermistor is located in the through hole 14.

The thermistor is inserted into the hollow cylinder 121, so that the thermistor can be conveniently mounted on one hand, and the thermistor is positioned in the hollow cylinder 121 on the other hand, so that the influence of the external environment temperature on the thermistor is avoided, and the measurement precision is further improved.

The pet house also comprises a memory, a WIFI module and a 2G module, wherein the memory is provided with a data input end and a data output end. The data input end of the memory is connected with the data output end of the processor, and the memory can store a target temperature value and a target weight value.

The WIFI module can establish data transmission connection with external equipment through a server. The WIFI module can send the target temperature value and the target weight value cached in the memory to the external device through the server.

The 2G module can establish data transmission connection with external equipment through the server. The 2G module can send the target temperature value and the target weight value cached in the memory to the external equipment through the server.

As shown in fig. 5, the processor determines whether the network status of the WIFI module is abnormal. If yes, uploading the target temperature mean value and the target weight value to external equipment through the server through the 2G module within the set time value.

The processor judges whether the network states of the WIFI module and the 2G module are both abnormal. If so, the target temperature value and the target weight value are temporarily stored in the memory, and under the condition that the WIFI module or the 2G network can be normally connected with the external equipment, the target temperature value and the target weight value are packed by the server and uploaded to the external equipment, and local data stored in the memory are cleared.

The external equipment can be a mobile phone, and the connection in a wireless communication mode ensures that the body temperature data and the weight data of the pet can be synchronized in the mobile phone. Because the domestic wireless communication mode is mainly WIFI, the problem that WIFI equipment is normally connected but the connection of the router upstream is abnormal easily occurs.

Therefore, when the network state of the WIFI module is abnormal, the physiological data of the pet are uploaded to the server through the 2G module, the problem that the connection between the WI-FI module and the server is abnormal is effectively solved through the dual-channel data uploading path, and the real-time performance of uploading the physiological data of the pet is higher. The physiological data of the pet can be uploaded timely, and the user experience is improved.

In addition, in order to prevent the problem of frequent network switching, when the network data of the WIFI module is abnormal, the 2G module is used for uploading data to the server within the following 10min, meanwhile, the connection state of the WIFI module and the server is monitored, and when the connection between the WI-FI module and the server is more than 5min continuously, the connection is normal, the WI-FI module is switched back to be connected with the server after 10 min.

The second embodiment of the invention provides a method for monitoring physiological data of a pet based on the pet nest, which comprises the following steps: the processor obtains temperature values input by a plurality of temperature sensors. And acquiring a first temperature value, a second temperature value and a third temperature value of which the temperature values are from high to low. And judging whether the temperature difference value of any two of the first temperature value, the second temperature value and the third temperature value is between 0 and 0.5 ℃.

If yes, judging whether the temperature difference value of the first temperature value and the second temperature value is between 0 and 0.2 ℃. If so, acquiring the temperature mean value of the first temperature value and the second temperature value, and taking the temperature mean value as a target temperature value.

According to the invention, the set temperature interval is most consistent with the actual temperature difference of each part of the pet by judging whether the temperature difference value of any two of the first temperature value, the second temperature value and the third temperature value is between 0 and 0.5 ℃ or not and judging whether the temperature difference value of the first temperature value and the second temperature value is between 0 and 0.2 ℃, and if the temperature difference value is not consistent with the set actual temperature difference, other temperature-equalizing objects can be possibly placed on the temperature-equalizing object, such as a hot water bag.

The monitoring method of the pet physiological data further comprises the following steps: the processor acquires a weight value acquired by the weighing sensor. A set number of weight values are obtained in a sliding window manner. The processor acquires a latest weight value, and the sliding window discards an initially acquired weight value.

The processor calculates a standard deviation of the weight values for the set amount in the sliding window. And judging whether the standard deviation is less than 0.2. If so, acquiring a weight average value of the weight values in the sliding window, and taking the weight average value as a target weight value.

For example, ten weight values are set in the sliding window, when the gravity data change occurs, the weighing sensor collects the gravity data according to the frequency of 1s once, the length of the sliding window is 10 collected weight values, when new data are collected once, the first data of the sliding window are discarded, the remaining 9 data move forward, and the new weight values are filled in the last position of the sliding window.

If the standard deviation of the data in the sliding window is less than 0.2, the weight value is considered to be stable, and if the standard deviation of the data in the sliding window is greater than or equal to 0.2, the sliding window continues to operate, so that the accuracy of pet weight measurement is improved.

Claims

1. A pet nest, comprising:

a socket (10) having a recess (11); the concave part (11) is used for the pet to lie prone;

a plurality of temperature sensors (20) having a temperature value acquisition terminal and a temperature value output terminal; the temperature acquisition ends of the plurality of temperature sensors (20) are arranged on the bottom surface of the concave part (11), and the temperature value output end can output the temperature value acquired by the temperature acquisition ends;

a processor having a data input and a data output; the data input end is connected with the temperature value output end, and the data input end can acquire a plurality of temperature values acquired by a plurality of temperature sensors (20); the processor can obtain a target temperature value according to the temperature sensors (20), and the data output end can output the target temperature value.

2. The pet nest of claim 1, characterized in that the nest body (10) has an inner cavity (13);

a bottom plate (12) of the concave part (11) is provided with a plurality of through holes (14); the through holes (14) are arranged in an array; the through hole (14) is communicated with the inner cavity (13);

the temperature sensors (20) are arranged in the inner cavity (13), the temperature acquisition ends are positioned in the through holes (14), and the temperature acquisition ends of the temperature sensors (20) protrude out of the bottom surface of the concave part (11).

3. The pet nest of claim 2, characterized in that the nest body (10) comprises:

the upper socket body (15) is provided with a concave part (11), a gap (152) is formed in the outer peripheral wall of the upper socket body (15), and an outward flange (151) is arranged on the upper edge of the upper socket body (15);

a lower socket body (16) which is provided with a lower concave part (161), wherein the upper edge of the lower socket body (16) is connected with the outward flange (151) of the upper socket body (15); an inner cavity (13) is formed between the inner peripheral wall of the lower socket body (16) and the outer peripheral wall of the upper socket body (15).

4. The pet nest of claim 3, further comprising:

a plurality of load cells (40) disposed on a bottom surface of the nest (16), the load cells (40) having a weight output connected to a data input of the processor;

wherein, the data input end of the processor can acquire a plurality of weight values acquired by a plurality of weighing sensors (40); the processor can obtain a target weight value based on the plurality of weight values, and the processor can output the target weight value.

5. The pet nest of claim 4, further comprising:

a heat shield (30) disposed on a back side of the base plate (12); the heat insulation plate (30) is positioned in the inner cavity (13); the heat insulation plate (30) is provided with a plurality of avoidance holes (31); the avoiding holes (31) correspond to the through holes (14) one by one.

6. The pet nest according to claim 2 or 3, characterized in that the through holes (14) comprise:

a middle through hole which is arranged in the middle of the bottom plate (12);

a plurality of outer ring through holes which are uniformly arranged on the bottom plate (12) at intervals around the middle through hole; six outer ring through holes are arranged around the middle through hole.

7. The pet nest of claim 6, characterized in that the back of the bottom plate (12) is connected or integrally formed with several hollow cylinders (121); the hollow cylinder (121) is correspondingly communicated with the through hole (14);

the temperature collector (20) is a thermistor; the thermistor is inserted into the hollow cylinder (121); one end of the thermistor is positioned in the through hole (14).

8. The pet nest of claim 4, further comprising:

a memory having a data input and a data output; the data input end of the memory is connected with the data output end of the processor, and the memory can store a target temperature value and a target weight value;

a WIFI module capable of establishing a data transmission connection with an external device; the WIFI module can send the target temperature value and the target weight value cached in the memory to external equipment through a server;

a 2G module capable of establishing a data transmission connection with an external device; the 2G module can send the target temperature value and the target weight value cached in the memory to external equipment through a server;

the processor judges whether the network state of the WIFI module is abnormal or not; if yes, uploading a target temperature mean value and a target weight value to the external equipment through the 2G module within a set time value;

the processor judges whether the network states of the WIFI module and the 2G module are both abnormal; if so, temporarily storing the target temperature value and the target weight value in the memory, and packaging and uploading the target temperature value and the target weight value to the server and clearing local data stored in the memory under the condition that the WIFI module or the 2G network can be normally connected with the server.

9. A method for monitoring physiological data of a pet in a pet house according to any one of claims 1 to 8, comprising:

the processor acquires temperature values input by a plurality of temperature sensors; acquiring a first temperature value, a second temperature value and a third temperature value of which the temperature values are from high to low;

judging whether the temperature difference value of any two of the first temperature value, the second temperature value and the third temperature value is between 0 and 0.5 ℃;

if yes, judging whether the temperature difference value of the first temperature value and the second temperature value is between 0 and 0.2 ℃;

10. The method for monitoring physiological data of pet according to claim 9, comprising:

the processor acquires a weight value acquired by the weighing sensor; acquiring a weight value of a set quantity in a sliding window mode;

the processor acquires a latest weight value, and the sliding window discards an initially acquired weight value;

the processor calculating a standard deviation of a set number of weight values in the sliding window; judging whether the standard deviation is less than 0.2;

and if so, acquiring a weight average value of the weight values in the sliding window, and taking the weight average value as a target weight value.