CN215346459U - Laboratory mouse monitoring system - Google Patents

Abstract

The utility model relates to a laboratory mouse monitoring system which comprises a box body, a weight monitoring unit, a drinking unit, a diet unit, a track monitoring unit, a food recovery unit and a control unit. The device has the advantages that through the dual arrangement of the diet unit and the food recovery unit, the diet weight of each experimental mouse in the box body can be accurately measured, and the measurement error is reduced; through the weighing improvement of the drinking unit, the water drinking amount of each experimental mouse in the box body can be accurately obtained without manual repeated measurement, so that the water drinking amount per hour and/or per day can be conveniently counted; the movement track of the experimental mouse is monitored through the track monitoring unit, the structure is simple, and the movement amount of each experimental mouse in the box body is accurately acquired.

Description

Laboratory mouse monitoring system

Technical Field

The utility model relates to the technical field of experimental devices, in particular to a laboratory mouse monitoring system.

Background

When the experimental mouse is fed, the accurate control of the feeding and water feeding of the experimental mouse and the real-time monitoring of the behavior of the experimental mouse are important links for ensuring the test precision.

In the related art, the food intake of a mouse is usually reversely estimated by weighing food. However, this method has a certain error. Due to the diet habit of the laboratory mouse, after the food is chewed by the laboratory mouse, part of the food is powdered and is raked on the padding, and if the difference of the weight of the food is measured to calculate the food intake, a large error exists. In addition, some special test materials (such as high-fat food) need to be stored at low temperature, but the conventional laboratory rat dragon is generally at normal temperature, and if the special test materials are not replaced, the special test materials are easy to deteriorate; if the special test material is frequently replaced, the behavior of the experimental mouse is influenced, and the test variable is not easy to control.

In the related art, the food intake of the mouse is usually reversely estimated by weighing a drinking water bottle. However, this approach has certain drawbacks. Because the hourly and/or daily water inflow of the laboratory mouse needs to be calculated, the drinking water bottle needs to be repeatedly weighed, the workload of testers is increased, and variables influencing the state of the laboratory mouse are increased.

In addition, in metabolic-related experiments on laboratory mice, the experimenter will generally pay more attention to the locomotor status of the laboratory mice. However, the existing metabolism cages are expensive and complex in structure, each metabolism cage can only observe a single experimental mouse, and the detection for more than one week can not be realized continuously.

At present, no effective solution is provided aiming at the problems of inaccurate diet and drinking water monitoring and incapability of continuously monitoring the motion state of a mouse in the related technology.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a laboratory mouse monitoring system aiming at the defects in the prior art, and at least solves the problems that the monitoring of diet and drinking water is inaccurate and the motion state of a mouse cannot be continuously monitored in the related technology.

In order to achieve the purpose, the utility model adopts the technical scheme that:

a laboratory mouse monitoring system comprising:

a box body;

weight monitoring unit, weight monitoring unit set up in the inside of box, weight monitoring unit includes:

the first accommodating space is provided with at least one first opening, and the volume of the first accommodating space can only accommodate one experimental mouse;

the first pressure sensor is arranged at the bottom of the first accommodating space;

at least one first communication sensor, wherein the first communication sensor is arranged at the top and/or the side of the first accommodating space;

the drinking water unit, the drinking water unit set up in the box, the drinking water unit includes:

the water storage container is arranged outside the box body or inside the box body;

the first end of the drinking water pipe is connected with the water storage container, the second end of the drinking water pipe is positioned inside the box body, and the second end of the drinking water pipe is lower than the first end of the drinking water pipe;

the second accommodating space is arranged at the second end of the drinking pipe, the second end of the drinking pipe is positioned in the second accommodating space, the second accommodating space is provided with at least one second opening, and the volume of the second accommodating space can only accommodate one experimental mouse;

the second pressure sensor is arranged at the bottom of the second accommodating space;

at least one second communication sensor, wherein the second communication sensor is arranged at the top and/or the side of the second accommodating space;

a diet unit disposed inside the case, the diet unit including:

the food storage container is arranged outside the box body or inside the box body;

the third accommodating space is arranged in the box body and is connected with the food storage container, the third accommodating space is provided with at least one third opening, and the volume of the third accommodating space can only accommodate one experimental mouse;

the baffle is rotatably arranged at the bottom of the third accommodating space;

the third pressure sensor is arranged at the bottom of the baffle;

at least one third communication sensor arranged at the top of the third accommodating space;

a track monitoring unit, the track monitoring unit set up in the inside of box, the track monitoring unit includes:

the fourth communication sensors are distributed in the box body;

the image sensors are distributed in the box body, and at least one image sensor is arranged around one fourth communication sensor;

a food recovery unit disposed inside the cabinet and positioned at a lower portion of the diet unit and aligned with the barrier;

the control unit is arranged inside the box body and/or outside the box body and is in communication connection with the weight monitoring unit, the drinking water unit, the diet unit and the track monitoring unit.

In some of these embodiments, the drinking unit further comprises:

the spherical body is embedded inside the second end of the drinking pipe, and the radius of the spherical body is larger than that of the second end of the drinking pipe;

under the condition of applying external force to the spherical body, the spherical body rolls along the drinking water pipe from the second end of the drinking water pipe to the first end of the drinking water pipe for a certain distance, so that the drinking water of the drinking water pipe flows out from the second end of the drinking water pipe; and under the condition that the external force applied to the spherical body is removed, the spherical body rolls towards the second end of the drinking water pipe along the drinking water pipe and blocks the second end of the drinking water pipe, so that the drinking water of the drinking water pipe cannot flow out from the second end of the drinking water pipe.

In some of these embodiments, the dietary unit further comprises:

a temperature control module set in the food storage container, and with the control unit communication connection is used for adjusting the temperature of the food storage container.

In some of these embodiments, the dietary unit further comprises:

the pushing module is arranged inside the food storage container, is in communication connection with the control unit, and is used for pushing food in the food storage container to the third accommodating space.

In some of these embodiments, the dietary unit further comprises:

a first end of the ramp is connected with the bottom surface of the interior of the box body, and a second end of the ramp is connected with the three accommodating spaces;

wherein the ramp is of a grid-like structure.

In some of these embodiments, the food recovery unit further comprises:

at least one fourth pressure sensor, the fourth pressure sensor set up in the bottom of food recovery unit to with the control unit communication connection.

In some of these embodiments, the drinking unit further comprises:

and the fifth pressure sensor is arranged at the bottom of the water storage container.

In some of these embodiments, further comprising:

a ventilation system provided in the case, the ventilation system including:

the first end of the air inlet pipe penetrates through the side wall of the box body, and the second end of the air inlet pipe is arranged outside the box body;

at least one exhaust pipe, the first end of exhaust pipe runs through the lateral wall setting of box, the second end of exhaust pipe set up in the outside of box, just the air-supply line with the exhaust pipe sets up and/or dislocation set relatively.

In some of these embodiments, the ventilation system further comprises:

and the fan is arranged at the second end of the air inlet pipe and/or the second end of the air exhaust pipe and is connected with the control unit.

In some of these embodiments, the ventilation system further comprises:

and the gas sensor is arranged in the box body and is in communication connection with the control unit.

In some of these embodiments, the waste recovery system further comprises:

the garbage container is arranged right below the third accommodating space and the ramp, and the fourth pressure sensor is arranged at the bottom of the garbage container;

wherein, the garbage container with the box is for dismantling the connection.

In some of these embodiments, the trash receptacle is a push-pull arrangement.

By adopting the technical scheme, compared with the prior art, the utility model has the following technical effects:

according to the laboratory mouse monitoring system, the diet unit and the food recovery unit are arranged in a double mode, the diet weight of each laboratory mouse in the box can be measured accurately, and the measurement error is reduced; through the weighing improvement of the drinking unit, the water drinking amount of each experimental mouse in the box body can be accurately obtained without manual repeated measurement, so that the water drinking amount per hour and/or per day can be conveniently counted; the movement track of the experimental mouse is monitored through the track monitoring unit, the structure is simple, and the movement amount of each experimental mouse in the box body is accurately acquired.

Drawings

FIG. 1 is a schematic view of an illustrative embodiment of the present invention;

FIG. 2 is a connection block diagram of electrical components of an exemplary embodiment of the present invention;

FIG. 3 is a schematic view of a housing of an exemplary embodiment of the present invention;

FIG. 4 is a schematic view of a drinking unit of an exemplary embodiment of the present invention;

FIG. 5 is a schematic view of a eating unit of an exemplary embodiment of the present invention;

FIG. 6 is a partial cross-sectional view of a eating member of an exemplary embodiment of the present invention;

FIG. 7 is a schematic view of a food recovery unit of an exemplary embodiment of the present invention;

FIG. 8 is a schematic view of a dunnage unit of an exemplary embodiment of the present invention;

FIG. 9 is a schematic view of a use state of an exemplary embodiment of the present invention.

Wherein the reference numerals are: 100. a box body; 101. a closure element; 102. grooving; 103. a grid plate; 104. a lifting module; 105. A cover plate;

200. a weight monitoring unit; 201. a first pressure sensor; 202. a first communication sensor;

300. a drinking water unit; 301. a water storage container; 302. a drinking pipe; 303. a second pressure sensor; 304. a second communication sensor; 305. a spherical body; 306. a fifth pressure sensor; 307. a flow sensor;

400. a diet unit; 401. a food storage container; 402. a baffle plate; 403. a third pressure sensor; 404. a third communication sensor; 405. A temperature control module; 406. a propulsion module; 407. a ramp;

500. a trajectory monitoring unit; 501. a fourth communication sensor; 502. an image sensor;

600. a food recovery unit; 601. a fourth pressure sensor; 602. a first recovery chamber;

700. a ventilation unit; 701. an air inlet pipe; 702. an exhaust duct; 703. a fan; 704. a gas sensor;

800. a dunnage unit; 801. a storage container; 802. cleaning the element; 803. a nozzle; 804. a switching element;

900. a control unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict.

The utility model is further described with reference to the following drawings and specific examples, which are not intended to be limiting.

The laboratory mouse monitoring system disclosed by the utility model comprises a box body 100, a weight monitoring unit 200, a drinking water unit 300, a diet unit 400, a track monitoring unit 500, a food recovery unit 600, a ventilation unit 700, a padding unit 800 and a control unit 900 as shown in figures 1-2. The weight monitoring unit 200 is disposed inside the box 100, the drinking water unit 300 is disposed inside the box 100, the diet unit 400 is disposed inside the box 100, the track monitoring unit 500 is disposed inside the box 100, the food recovery unit 600 is disposed inside the box 100, the ventilation unit 700 is disposed inside the box 100, the padding unit 800 is disposed inside the box 100, and the control unit 900 is disposed inside and/or outside the box 100 and is in communication connection with the weight monitoring unit 200, the drinking water unit 300, the diet unit 400, the track monitoring unit 500, the ventilation unit 700, and the padding unit 800, respectively.

As shown in fig. 3, the casing 100 is an openable and closable closed type rearing or cultivation casing, which may be made entirely of a transparent material, may be made entirely of a non-transparent material, or may be made of a mixture of a transparent material and a non-transparent material (i.e., a part of the casing 100 is made of a non-transparent material and a part is made of a transparent material for easy observation).

The case 100 includes a closing member 101, and the closing member 101 is disposed at a side portion or a top portion of the case 100 to facilitate a tester to put a mouse into the case 100 or take the mouse from the case 100.

In some of these embodiments, closure element 101 is pivotally connected to case 100, including but not limited to a hinge connection.

In some of these embodiments, the closure element 101 is snap-fitted to the housing 100, being locked by means of several snap-fit elements.

The box body 100 is further opened with a slot 102 for the food recovery unit 600, and the slot 102 is disposed at a side portion of the box body 100.

The box 100 further includes a grid plate 103, and the grid plate 103 is closely attached to the bottom of the box 100.

The box 100 further comprises a lifting module 104, wherein the lifting module 104 is connected to the grid plate 103 and is in communication with the control unit 900 for lifting or lowering the grid plate 103. Specifically, the lifting module 104 is arranged at the bottom of the interior of the box body 100, the grid plate 103 is connected with the top of the lifting module 104, and the grid plate 103 is arranged close to the bottom side of the interior of the box body 100 under the condition that padding in the box body 100 does not need to be cleaned; under the condition of cleaning the padding in the box body 100, the control unit 900 controls the lifting module 104 to move, so that the grid plate 103 is lifted, the laboratory mouse and the padding are separated, and the padding can be cleaned and replaced under the condition that the laboratory mouse is not influenced.

In some embodiments, the lifting module 104 is a screw driving module, and includes a motor and a plurality of telescopic screws, and the motor drives the plurality of telescopic screws to move, so as to lengthen or shorten the telescopic screws, thereby driving the grid plate 103 to ascend or descend.

In some of these embodiments, the lifting module 104 is a sliding transmission module, and includes a motor (disposed in the sidewall of the box 100) and a plurality of sliding rods, which are symmetrically disposed on the sidewall of the grid plate 103. Correspondingly, the side wall of the box 100 is provided with a plurality of sliding rails and a limiting element for enabling the sliding rod to slide along the sliding rails and to stay at a specific position.

The housing 100 further includes a cover 105, the cover 105 being removably attachable to the slot 102, including but not limited to a snap fit, snap fit connection, etc.

In some embodiments, the housing 100 further includes an escape prevention screen (not shown) detachably disposed at an upper side of the inside of the housing 100 for preventing the laboratory mouse from escaping.

As shown in fig. 1 to 2, the weight monitoring unit 200 is disposed inside the box 100 and on the upper side of the grid plate 103. The weight monitoring unit 200 comprises at least one first accommodating space (not shown), at least one first pressure sensor 201, and at least one first communication sensor 202, wherein a first pressure sensor 201 is disposed at the bottom of each first accommodating space, and a first communication sensor 202 is disposed inside each first accommodating space.

The first containing space is provided with at least one first opening for the laboratory mouse to enter the inside of the first containing space through the first opening or leave the first containing space.

In addition, the first accommodating space has a volume capable of accommodating only one laboratory mouse.

In some embodiments, the first accommodating space is provided with at most two first openings, wherein one first opening is used for allowing the laboratory mouse to enter the first accommodating space, and the other first opening is used for allowing the laboratory mouse to leave the first accommodating space.

The first pressure sensor 201 is disposed at the bottom of the first accommodating space, and is in communication connection with the control unit 900, and is configured to detect the weight of the laboratory mouse entering the first accommodating space, so as to transmit the weight data of the laboratory mouse to the control unit 900.

First communication sensor 202 sets up the inside of first accommodation space to with the control unit 900 communication connection, be used for discerning the laboratory mouse that gets into first accommodation space, thereby discernment laboratory mouse's serial number, and transmit laboratory mouse's serial number to the control unit 900, the control unit 900 carries out the one-to-one with laboratory mouse's serial number, laboratory mouse's weight data and stores and outwards transmits.

In some embodiments, the communication chip carried by the laboratory mouse is a Radio Frequency chip, including but not limited to a Radio Frequency Identification chip (RFID chip). Correspondingly, the first communication sensor 202 is a radio frequency sensor.

In some of these embodiments, the laboratory mice carry a fluorescent label, which is different from one laboratory mouse to another. Correspondingly, the first communication sensor 202 is an image sensor.

In some embodiments, the weight monitoring unit 200 comprises a plurality of first accommodating spaces, a plurality of first pressure sensors 201, and a plurality of first communication sensors 202, so as to measure the weight data of a plurality of experimental mice simultaneously.

As shown in fig. 4, the drinking unit 300 includes at least one water storage container 301, at least one drinking water pipe 302, at least one second accommodating space (not shown), at least one second pressure sensor 303, and at least one second communication sensor 304. Wherein, the water storage container 301 is arranged inside or outside the box body 100; a first end of the drinking water pipe 302 is connected with the water storage container 301, and a second end of the drinking water pipe 302 is positioned inside the box body 100; the second accommodating space is arranged inside the box body 100 and is connected with the second end of the drinking water pipe 302; the second pressure sensor 303 is disposed at the bottom of the second accommodating space; the second communication sensor 304 is disposed inside the second accommodating space.

In some embodiments, the water storage container 301 is disposed outside the tank 100 and detachably connected to the tank 100, including but not limited to plugging.

The drinking tube 302 is arranged at an inclination, i.e. the second end of the drinking tube 302 is located at a lower level than the first end of the drinking tube 302, so that water flows down the drinking tube 302.

In some of these embodiments, the drinking unit 300 further includes a spherical body 305, the spherical body 305 is embedded in the second end of the drinking tube 302, and the spherical body 305 is completely located inside the drinking tube 302. The radius of the spherical body 305 is larger than the radius of the second end of the drinking tube 302, so that the spherical body 305 cannot fall off the second end of the drinking tube 302.

Specifically, in the use process, under the condition that an external force is applied to the spherical body 305 (i.e. a laboratory mouse licks the spherical body 305 to apply the external force), the spherical body 305 rolls along the drinking water pipe 302 from the second end of the drinking water pipe 302 to the first end of the drinking water pipe 302 for a certain distance, so that the drinking water in the drinking water pipe 302 flows out from the second end of the drinking water pipe 302; when the external force applied to the spherical body 305 is removed, the spherical body 305 rolls along the drinking tube 302 toward the second end of the drinking tube 302 and blocks the second end of the drinking tube 302, so that the drinking water in the drinking tube 302 cannot flow out of the second end of the drinking tube 302.

The second accommodating space is provided with at least one second opening for the laboratory mouse to enter the inside of the second accommodating space through the second opening or leave the second accommodating space.

In addition, the second accommodating space has a volume capable of accommodating only one laboratory mouse.

In some embodiments, the second accommodating space is provided with at most two second openings, wherein one second opening is used for allowing the laboratory mouse to enter the second accommodating space, and the other second opening is used for allowing the laboratory mouse to leave the second accommodating space.

The second pressure sensor 303 is disposed at the bottom of the second accommodating space, and is in communication connection with the control unit 900, and is configured to detect the weight of the laboratory mouse entering the second accommodating space, so as to transmit the weight data of the laboratory mouse to the control unit 900. Wherein the weight data comprises weight data of the laboratory mouse entering the second accommodating space and weight data of the laboratory mouse leaving the second accommodating space. The water intake of the experimental mouse can be obtained through two times of weight data.

The second communication sensor 304 is arranged inside the second accommodating space, is in communication connection with the control unit 900, and is used for identifying the laboratory mouse entering the second accommodating space, so that the serial number of the laboratory mouse is identified, the serial number of the laboratory mouse is transmitted to the control unit 900, and the control unit 900 stores the serial number of the laboratory mouse and the weight data of the laboratory mouse in a one-to-one correspondence manner and transmits the data outwards.

In some embodiments, the communication chip carried by the laboratory mouse is a Radio Frequency chip, including but not limited to a Radio Frequency Identification chip (RFID chip). Correspondingly, the second communication sensor 304 is a radio frequency sensor.

In some of these embodiments, the laboratory mice carry a fluorescent label, which is different from one laboratory mouse to another. Correspondingly, the second communication sensor 304 is an image sensor.

In some embodiments, the drinking water unit 300 further includes a fifth pressure sensor 306, and the fifth pressure sensor 306 is disposed at the bottom of the water storage container 301 and is in communication with the control unit 900 for monitoring the weight of the water storage container 301.

In some embodiments, the drinking unit 300 further includes a flow sensor 307, and the flow sensor 307 is disposed at the second end of the spherical body 305 or the drinking tube 302 and is in communication with the control unit 900 for calculating the drinking volume of the laboratory mouse.

In some embodiments, the ball 305 is a metering gear with a communication function, and when the laboratory mouse pushes the ball 305, the number of rotations of the ball 305 can be converted into the volume (or flow rate) of drinking water.

In some embodiments, the drinking unit 300 includes a water storage container 301, a plurality of drinking water pipes 302 (each drinking water pipe 302 is individually connected to the water storage container 301), a plurality of second receiving spaces (each second receiving space is individually connected to a drinking water pipe 302), a plurality of second pressure sensors 303 (a second pressure sensor 303 is disposed at the bottom of each second receiving space), a plurality of second communication sensors 304 (a second communication sensor 304 is disposed inside each second receiving space), a plurality of balls 305 (a ball 305 is disposed at the second end of each drinking water pipe 302), and a fifth pressure sensor 306, so as to meet the requirement of a plurality of laboratory mice for drinking water at the same time.

As shown in fig. 5 to 6, the eating unit 400 includes a food container 401, at least one third accommodating space (not shown), at least one baffle 402, at least one third pressure sensor 403, at least one third communication sensor 404, at least one temperature control module 405, at least one propulsion module 406, and at least one ramp 407. Wherein, the food storage container 401 is arranged inside the box body 100 or outside the box body 100; the third receiving space is provided inside the case 100 and connected to the food storage container 401; the baffle 402 is rotatably disposed at the bottom of the third accommodating space; the third pressure sensor 403 is arranged at the bottom of the baffle 402; the third communication sensor 404 is disposed inside the third accommodation space; the temperature control module 405 is arranged inside the food storage container 401; the propelling module 406 is arranged inside the food storage container 401; the ramp 407 is disposed inside the box 100, a first end of the ramp 407 is connected to the food storage container 401, and a second end of the ramp 407 is connected to the mesh plate 103.

In some embodiments, the food storage container 401 is disposed outside the housing 100 and is removably connected to the housing 100, including but not limited to being plugged.

In some of these embodiments, the food storage container 401 is arranged inside the box 100, and is provided with a conveying pipe, a first end of the conveying pipe is connected with the food storage container 401, and a second end of the conveying pipe penetrates through the side wall (top or side) of the box 100; a closure element is also provided at the second end of the delivery tube for closing the second end of the delivery tube.

The third receiving space is connected with the food storage container 401 through a guide tube, and the guide tube is obliquely arranged so that the food in the food storage container 401 slides down to the third receiving space through the guide tube.

The third accommodating space is provided with at least one third opening for the laboratory mouse to enter the inside of the third accommodating space through the third opening or leave the third accommodating space.

In addition, the third accommodating space has a volume capable of accommodating only one laboratory mouse.

The baffle 402 is rotatably disposed at the bottom of the third accommodating space, and the rotating shaft is an electrically controlled rotating shaft and is in communication connection with the control unit 900, so as to turn over the food positioned on the baffle 402 to the food recovery unit 600 under the condition that the control unit 900 issues an instruction. The purpose of adopting this kind of baffle is, abandoning stale food, avoids laboratory mouse to eat by mistake, prevents that the experimental data from having the error.

The third pressure sensor 403 is disposed at the bottom of the baffle 402 and is in communication with the control unit 900 for detecting the weight of the food on the baffle 402 and transmitting the food weight data to the control unit 900.

Third communication sensor 404 sets up in third accommodation space's inside to with the control unit 900 communication connection, be used for discerning the laboratory mouse that gets into third accommodation space, thereby discerning laboratory mouse's serial number, and transmit laboratory mouse's serial number to the control unit 900, the control unit 900 carries out the one-to-one with laboratory mouse's serial number, laboratory mouse's weight data and stores and outwards transmits.

In some embodiments, the communication chip carried by the laboratory mouse is a Radio Frequency chip, including but not limited to a Radio Frequency Identification chip (RFID chip). Correspondingly, the third communication sensor 404 is a radio frequency sensor.

In some of these embodiments, the laboratory mice carry a fluorescent label, which is different from one laboratory mouse to another. Correspondingly, the third communication sensor 404 is an image sensor.

The temperature control module 405 is disposed inside the food storage container 401, and is in communication connection with the control unit 900, and is configured to control the temperature of the food storage container 401, so that the food in the food storage container 401 is in an optimal storage environment for a long time (at least 15 days), and the food is prevented from deteriorating.

In some of these embodiments, the temperature control module 405 is a semiconductor temperature control module capable of cooling and heating to meet the preservation requirements of different foods.

In some of these embodiments, the temperature control module 405 is disposed at the bottom and/or side of the food storage container 401 to make the temperature distribution in the food storage container 401 uniform.

The pushing module 406 is disposed inside the food storage container 401 and at least comprises a pushing motor, a pushing baffle and a pushing shaft, the pushing baffle is connected with the pushing motor through the pushing shaft, and under the action of the pushing motor, the pushing shaft reciprocates to enable the pushing baffle to reciprocate in the linear direction, so that food in the food storage container 401 is pushed to the conveying pipe and falls into the third accommodating space from the conveying pipe.

In some embodiments, the pushing module 406 further comprises a closing flap, the closing flap is disposed at the first end of the conveying pipe, and when the closing flap is connected to the pushing motor through the transmission element, the closing flap is opened to allow the food to enter the conveying pipe when the pushing motor drives the pushing flap to move forward; when the pushing motor drives the pushing baffle to move backwards, the closing baffle is closed to prevent food from entering the conveying pipe.

The ramp 407 is disposed inside the box 100, and is inclined at a certain angle, so that the laboratory mouse can climb up along the ramp 407 to enter the third accommodating space.

Wherein, ramp 407 is the latticed structure to make the residue that the laboratory mouse chewed food produced fall into food recovery unit 600 through ramp 407, avoid food residue to stop on ramp 407, influence the monitoring of laboratory mouse weight data.

In addition, the both sides of ramp 407 still are provided with the protective wall, avoid the laboratory mouse to drop from ramp 407.

In some embodiments, the diet unit 400 includes a plurality of food storage containers 401, a plurality of third receiving spaces (each food storage container 401 corresponds to a third receiving space), a plurality of baffles 402 (a baffle 402 is disposed at the bottom of each third receiving space), a plurality of third pressure sensors 403 (a third pressure sensor 403 is disposed at the bottom of each baffle 402), a plurality of third communication sensors 404 (a third communication sensor 404 is disposed inside each third receiving space), a plurality of temperature control modules 405 (a temperature control module 405 is disposed inside each food storage container 401), a plurality of propulsion modules 406 (a propulsion module 406 is disposed inside each food storage container 401), and a plurality of ramps 407 (a ramp 407 is disposed in each third receiving space), so as to satisfy the requirement that a plurality of laboratory mice eat food at the same time.

The trajectory monitoring unit 500 includes a number of fourth communication sensors 501 and a number of image sensors 502. The fourth communication sensors 501 are disposed inside the box 100, and the image sensors 502 are disposed inside the box 100.

The fourth communication sensors 501 are in communication connection with the control unit 900, and are configured to identify the laboratory mouse in the box 100, so as to identify the serial number of the laboratory mouse, and transmit the serial number of the laboratory mouse to the control unit 900.

In some embodiments, the communication chip carried by the laboratory mouse is a Radio Frequency chip, including but not limited to a Radio Frequency Identification chip (RFID chip). Correspondingly, the fourth communication sensor 501 is a radio frequency sensor.

The image sensors 502 are respectively in communication connection with the control unit 900, and are configured to record a track of the laboratory mouse in the box 100 and transmit a track image of the laboratory mouse to the control unit 900.

Generally, an image sensor 502 is disposed beside each fourth communication sensor 501, and in the case where a laboratory mouse passes through the fourth communication sensor 501, the image sensor 502 acquires image data (including still image data and moving image data) of the laboratory mouse.

As shown in fig. 7, the food recovery unit 600 includes a fourth pressure sensor 601 and a first recovery cavity 602. Wherein the first recycling chamber 602 is disposed below the eating unit 400, and the fourth pressure sensor 601 is disposed at the bottom of the first recycling chamber 602.

The first recycling chamber 602 is detachably disposed below the eating unit 400 and is used for receiving the food dropped by the baffle 402 and the food dropped by the ramp 407.

The fourth pressure sensor 601 is communicatively connected to the control unit 900, and is configured to monitor the weight data of the first recycling chamber 602 and transmit the weight data to the control unit 900.

Wherein the first recycling cavity 602 corresponds to an opening 102.

The ventilation unit 700 includes at least one air inlet duct 701, at least one air outlet duct 702, at least one fan 703 and at least one gas sensor 704. The air inlet pipe 701 is disposed at one side of the box 100, the air outlet pipe 702 is disposed corresponding to the air inlet pipe 701, the fan 703 is disposed at one side of the air inlet pipe 701, and the gas sensor 704 is disposed inside the box 100.

The air inlet pipe 701 penetrates through the side wall of the box body 100, and filter screens are arranged at two ends of the air inlet pipe 701.

The exhaust duct 702 penetrates the sidewall of the box 100, and both ends of the exhaust duct 702 are provided with filter screens.

In some embodiments, the exhaust duct 702 is disposed symmetrically to the air inlet duct 701, i.e. the air inlet duct 701 is disposed on the left side wall of the box 100, and the exhaust duct 702 is disposed on the right side wall of the box 100; the exhaust duct 702 is disposed asymmetrically with respect to the air inlet duct 701, that is, the air inlet duct 701 is disposed on the left side wall of the box body 100, and the exhaust duct 702 is disposed on the front side wall/rear side wall/upper side wall of the box body 100.

A fan 703 is disposed outside the cabinet 100 in alignment with the air inlet duct 701 and is in communication with the control unit 900 for increasing the flow rate of air to the cabinet 100 under certain conditions.

The gas sensor 704 is disposed inside the housing 100 and is in communication with the control unit 900 for monitoring gas data, including but not limited to carbon dioxide concentration, within the housing 100 and transmitting the gas data to the control unit 900.

As shown in fig. 8, the dunnage unit 800 includes a storage container 801, a cleaning element 802, a nozzle 803, and a switch element 804. The magazine 801 is disposed outside the housing 100, the cleaning element 802 is disposed inside the housing 100, the nozzle 803 is disposed on the cleaning element 802 and connected to the magazine 801, and the switch element 804 is disposed on the bottom side of the interior of the housing 100.

A cleaning element 802 is provided inside the box 100, between the grid plate 103 and the bottom of the interior of the box 100, and in communicative connection with the control unit 900, for pushing the dunnage of the box 100 to one side of the box 100 with the grid plate 103 raised; and returns to the initial position when the pushing is completed.

In some of these embodiments, the cleaning element 802 is a T-shaped cleaning blade comprising a cross plate and a vertical post, wherein the vertical post is a telescoping structure.

Further, the horizontal plate of the cleaning element 802 is embedded in the side wall of the box 100, and the vertical rod is located outside the box 100.

The nozzle 803 is disposed at the front side of the cleaning element 802, i.e., at the transverse plate of the cleaning element 802, and is in communication with the control unit 900 for sucking the dunnage from the storage container 801 and spraying it into the interior of the box 100 after the cleaning of the dunnage is completed.

Specifically, the nozzles 803 are uniformly distributed on the horizontal plate of the cleaning element 802, and the cleaning element 802 is a hollow structure.

The switch element 804 is disposed at the bottom of the case 100 and is communicatively connected to the control unit 900. Correspondingly, the bottom of the box 100 is provided with a dunnage discharge port (not shown), and the switching element 804 is disposed to close the dunnage discharge port.

In some of these embodiments, the switch element 804 is a magnetic switch.

The control unit 900 is disposed inside or outside the box 100, and is a circuit board mounted with a plurality of electrical components, and is configured to receive relevant data transmitted by the weight monitoring unit 200, the drinking water unit 300, the eating unit 400, the trajectory monitoring unit 500, and the ventilation unit 700, and control the eating unit 400 and the ventilation unit 700.

The specific embodiment of the utility model is as follows:

and (3) food preservation: the control unit 900 sends a temperature control signal to the temperature control module 405 of the eating unit 400 to adjust the temperature of the food storage container 401, so as to ensure that the food in the food storage container 401 can be preserved for a long time (at least 15 days);

diet monitoring: when the laboratory mouse eats, the identity tag of the laboratory mouse can be read by the third communication sensor 404, the third accommodating space can only accommodate one laboratory mouse to eat, the reduction of the weight of the food on the baffle plate 402 and the increase of the weight of the food in the first recovery cavity 602 can be obtained by monitoring the weight of the food on the baffle plate 402 and the weight of the food in the first recovery cavity 602, and the difference between the two data is the food consumption of the laboratory mouse;

perishable food renewal: when the food on the baffle 402 disappears or is reduced to a certain weight, the control unit 900 sends a control signal to the pushing module 406 to control the pushing module 406 to work, so that the food in the food storage container 401 enters the baffle 402 of the third accommodating chamber;

collection and weighing of expired food: after the food on the baffle 402 is exposed to the air for a certain time, the control unit 900 controls the baffle 402 to rotate, so that the food on the baffle 402 falls into the first recycling cavity 602 and the baffle 402 is reset;

food waste collection and weighing: the laboratory mouse has a habit of gnawing food, the broken slag formed in the process of gnawing the food can not be eaten by the laboratory mouse generally, the ramp 407 is connected with the food on the baffle 402 at a certain inclination angle, the waste food broken slag can fall into the first recovery cavity 602 and be weighed, and the actual food consumption of the laboratory mouse is not counted;

drinking water monitoring: the second pressure sensor 303 monitors the weight data of the laboratory mouse for the first time when the laboratory mouse enters the second accommodating space, and the second pressure sensor 303 monitors the weight data of the laboratory mouse for the second time when the laboratory mouse leaves the second accommodating space; the difference between the two data is the water intake of the experimental mouse; or, the flow sensor 307 is used for monitoring the water intake of the experimental mouse each time, and the flow data transmitted by the flow sensor 307 before and after drinking water is used for calculation (namely, the water intake volume is calculated by using the relation between the flow and the time);

and (3) water addition monitoring: the fifth pressure sensor 306 monitors the weight of the water storage container 301, and when the weight of the water storage container 301 reaches a certain threshold value, the control unit 900 transmits a signal to the outside to remind a tester of adding water to the water storage container 301;

monitoring the body weight: when the laboratory mouse enters the first accommodating space, the identity tag of the laboratory mouse can be read by the first communication sensor 202, the weight data of the laboratory mouse can be monitored by the first pressure sensor 201, and the first accommodating space can only accommodate one laboratory mouse for weight monitoring;

monitoring the movement: monitoring the track of each experimental mouse by a track monitoring unit 500, reading the identity label of each experimental mouse by using a fourth communication sensor 501, acquiring the image data of the experimental mouse in the box 100 by using an image sensor 502, setting a fluorescent mark on each experimental mouse, and acquiring the daily/weekly/monthly exercise amount of each experimental mouse by using dual identity authentication;

cleaning padding: the grid plate 103 is lifted periodically through the lifting module 104, so that a laboratory mouse positioned on the grid plate 103 is lifted to be separated from the padding; as shown in fig. 9, the control unit 900 controls the movement of the cleaning element 802 such that the dunnage of the box 100 is pushed to the dunnage discharge port, at which time the switching element 804 is actuated to expose the dunnage discharge port and waste dunnage is discharged from the dunnage discharge port; after completion of the dunnage discharge, the cleaning element 802 is reset and the switching element 804 closes the dunnage discharge port; the control unit 900 controls the nozzles 803 to uniformly spray the dunnage in the storage container 801 to the bottom of the box 100.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (10)

1. A laboratory mouse monitoring system, comprising:

a box body;

weight monitoring unit, weight monitoring unit set up in the inside of box, weight monitoring unit includes:

the first accommodating space is provided with at least one first opening, and the volume of the first accommodating space can only accommodate one experimental mouse;

the first pressure sensor is arranged at the bottom of the first accommodating space;

at least one first communication sensor, wherein the first communication sensor is arranged at the top and/or the side of the first accommodating space;

the drinking water unit, the drinking water unit set up in the box, the drinking water unit includes:

the water storage container is arranged outside the box body or inside the box body;

the first end of the drinking water pipe is connected with the water storage container, the second end of the drinking water pipe is positioned inside the box body, and the second end of the drinking water pipe is lower than the first end of the drinking water pipe;

the second accommodating space is arranged at the second end of the drinking pipe, the second end of the drinking pipe is positioned in the second accommodating space, the second accommodating space is provided with at least one second opening, and the volume of the second accommodating space can only accommodate one experimental mouse;

the second pressure sensor is arranged at the bottom of the second accommodating space;

at least one second communication sensor, wherein the second communication sensor is arranged at the top and/or the side of the second accommodating space;

a diet unit disposed inside the case, the diet unit including:

the food storage container is arranged outside the box body or inside the box body;

the third accommodating space is arranged in the box body and is connected with the food storage container, the third accommodating space is provided with at least one third opening, and the volume of the third accommodating space can only accommodate one experimental mouse;

the baffle is rotatably arranged at the bottom of the third accommodating space;

the third pressure sensor is arranged at the bottom of the baffle;

at least one third communication sensor arranged at the top of the third accommodating space;

a track monitoring unit, the track monitoring unit set up in the inside of box, the track monitoring unit includes:

the fourth communication sensors are distributed in the box body;

the image sensors are distributed in the box body, and at least one image sensor is arranged around one fourth communication sensor;

a food recovery unit disposed inside the cabinet and positioned at a lower portion of the diet unit and aligned with the barrier;

the control unit is arranged inside the box body and/or outside the box body and is in communication connection with the weight monitoring unit, the drinking water unit, the diet unit and the track monitoring unit.

2. The laboratory mouse monitoring system according to claim 1, wherein said drinking water unit further comprises:

the spherical body is embedded inside the second end of the drinking pipe, and the radius of the spherical body is larger than that of the second end of the drinking pipe;

under the condition of applying external force to the spherical body, the spherical body rolls along the drinking water pipe from the second end of the drinking water pipe to the first end of the drinking water pipe for a certain distance, so that the drinking water of the drinking water pipe flows out from the second end of the drinking water pipe; and under the condition that the external force applied to the spherical body is removed, the spherical body rolls towards the second end of the drinking water pipe along the drinking water pipe and blocks the second end of the drinking water pipe, so that the drinking water of the drinking water pipe cannot flow out from the second end of the drinking water pipe.

3. The laboratory mouse monitoring system according to claim 1, wherein said diet unit further comprises:

a temperature control module set in the food storage container, and with the control unit communication connection is used for adjusting the temperature of the food storage container.

4. The laboratory mouse monitoring system according to claim 1, wherein said diet unit further comprises:

the pushing module is arranged inside the food storage container, is in communication connection with the control unit, and is used for pushing food in the food storage container to the third accommodating space.

5. The laboratory mouse monitoring system according to claim 1, wherein said diet unit further comprises:

a first end of the ramp is connected with the bottom surface of the interior of the box body, and a second end of the ramp is connected with the three accommodating spaces;

wherein the ramp is of a grid-like structure.

6. The laboratory mouse monitoring system according to claim 1, wherein said food recovery unit further comprises:

at least one fourth pressure sensor, the fourth pressure sensor set up in the bottom of food recovery unit to with the control unit communication connection.

7. The laboratory mouse monitoring system according to claim 1, wherein said drinking water unit further comprises:

and the fifth pressure sensor is arranged at the bottom of the water storage container.

8. The laboratory mouse monitoring system according to claim 1, further comprising:

a ventilation system provided in the case, the ventilation system including:

the first end of the air inlet pipe penetrates through the side wall of the box body, and the second end of the air inlet pipe is arranged outside the box body;

at least one exhaust pipe, the first end of exhaust pipe runs through the lateral wall setting of box, the second end of exhaust pipe set up in the outside of box, just the air-supply line with the exhaust pipe sets up and/or dislocation set relatively.

9. The laboratory mouse monitoring system according to claim 8, wherein said ventilation system further comprises:

and the fan is arranged at the second end of the air inlet pipe and/or the second end of the air exhaust pipe and is connected with the control unit.

10. The laboratory mouse monitoring system according to claim 9, wherein said ventilation system further comprises:

and the gas sensor is arranged in the box body and is in communication connection with the control unit.

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