CN219084387U - Intelligent closestool heating stability test system - Google Patents

Abstract

The application relates to an intelligent closestool heating stability test system relates to the intelligent closestool check out test set field. The liquid storage rack comprises a rack body, a first liquid storage tank is arranged on the rack body, a heating piece for driving liquid to heat is arranged in the first liquid storage tank, a plurality of temperature sensors are fixed in the first liquid storage tank, a multipoint temperature recorder is fixed on the rack body, the temperature sensors are electrically connected with the multipoint temperature recorder, an infusion piece for infusing the liquid into the first liquid storage tank is arranged on the first liquid storage tank, and a liquid outlet piece for discharging the liquid is also arranged on the first liquid storage tank. This application has the effect of being convenient for the operator to make the experiment to the heating stability of heating element in the intelligent closestool.

Description

Intelligent closestool heating stability test system

Technical Field

The application relates to intelligent closestool check out test set field especially relates to an intelligent closestool heating stability test system.

Background

The intelligent closestool is different from the common closestool in function, namely the intelligent closestool can be used for cleaning the parts of a human body, the temperature in the pipeline system of the intelligent closestool can damage the human body when the temperature is too high, and the experience of people can be influenced when the temperature is too low, so that a manufacturer can test the heating performance of the intelligent closestool before selling the intelligent closestool.

The utility model patent with the application number of CN211547951U discloses an intelligent closestool heating component comprehensive testing machine which comprises a code scanning mechanism, a testing module, a control system and a pipeline system; the control system is connected with the code scanning mechanism, the test module, the high-precision detection switch of the pipeline system and other components; the code scanning mechanism is used for collecting information of the part to be tested and transmitting the information to the control system; the testing module comprises a water inlet mechanism, a pressure detection mechanism, a resistance detection mechanism, a sealing performance detection mechanism and a knob fixing mechanism; the related components of the pipeline system are connected with the control system and comprise an air source pipeline and a water source pipeline, the air source pipeline and the water source pipeline are communicated with the water inlet mechanism, and the water source pipeline is provided with a pressure gauge and a flowmeter; the test module still includes fixed establishment, fixed establishment includes fixing base and clamping mechanism, the fixing base is used for placing the heating element that awaits measuring, clamping mechanism includes cylinder and pressure head, the cylinder sets up in the fixing base top, the pressure head is from the top down driven by the cylinder and is tightly fixed the heating element that awaits measuring.

The inventor considers that when the intelligent closestool heating component comprehensive testing machine is used for testing, an operator needs to install a heating component to be tested on a fixed seat, a knob fixing mechanism is used for fixing a water outlet control switch of the heating component to be tested, a starting button is pressed by two hands, a clamping mechanism presses down and fixes the heating component to be tested, a water inlet mechanism is in butt joint with a water inlet, and then testing is carried out according to a programmable controller and an upper computer display, however, in actual operation, the operator only supports temperature detection of the heating component when operating the intelligent closestool heating component comprehensive testing machine, does not carry out temperature detection on each liquid level of liquid, and measures the heating stability of the liquid inaccurately.

Disclosure of Invention

In order to test the heating stability of liquid when an operator measures the liquid, the application provides an intelligent closestool heating stability test system.

The application provides an intelligent closestool heating stability test system adopts following technical scheme:

the utility model provides an intelligent closestool heating stability test system, includes the support body, install first liquid reserve tank on the support body, be provided with the heating piece that is used for driving liquid heating in the first liquid reserve tank, first liquid reserve tank internal fixation has temperature sensor, be fixed with the multiple spot temperature recorder on the support body, temperature sensor with multiple spot temperature recorder electricity is connected, be provided with the infusion piece that is used for to first liquid reserve tank infusion on the first liquid reserve tank, still be provided with on the first liquid reserve tank and be used for liquid exhaust drain.

Through adopting above-mentioned technical scheme, when the operator needs to use test intelligent closestool temperature rise performance, the operator needs to pass through infusion subassembly earlier and infuse in the first liquid reserve tank, then the operator heats first liquid reserve tank liquid through the heating element, temperature sensor passes first liquid reserve tank interior liquid temperature to the multiple spot temperature recorder in real time, when the multiple spot temperature recorder shows the temperature for appointed temperature, the operator records current multiple spot temperature recorder recording time, this test heating element's heating performance, the operator discharges first liquid reserve tank interior liquid through the play liquid spare in appointed time, then the operator passes through temperature sensor and measures first liquid reserve tank interior residual liquid temperature, and whether the liquid still is at appointed temperature value through multiple spot temperature recorder check first liquid reserve tank, this test liquid is at the temperature value of this liquid level, repeatedly above-mentioned test, the heating stability of heating element is measured, thereby set up each liquid level temperature value when being convenient for the operator to test each liquid heats.

Optionally, the heating element is configured as a first electrothermal tube, the first electrothermal tube is fixedly connected in the first liquid storage tank, and the first electrothermal tube is electrically connected with the multipoint temperature recorder.

Through adopting above-mentioned technical scheme, when the operator needs to heat the liquid in the first liquid reserve tank, the operator heats the liquid in the first liquid reserve tank through first electrothermal tube, then whether reaches appointed temperature value through temperature sensor measurement liquid surface.

Optionally, the infusion part is arranged as an infusion pipeline connected to the first liquid storage tank, and the infusion pipeline is communicated with an external waterway.

Through adopting above-mentioned technical scheme, when the operator needs to infuse liquid in the first liquid reserve tank, the operator infuses the pipeline through external water route to the infusion, and liquid flows into in the first liquid reserve tank through the pipeline, accomplishes first liquid reserve tank infusion operation.

The liquid draining assembly comprises a liquid outlet pipeline connected to the first liquid storage tank and a first electromagnetic valve fixed at the communication position of the first liquid storage tank and the liquid outlet pipeline.

Through adopting above-mentioned technical scheme, when the operator needs to be with the liquid discharge in the first liquid reserve tank, the operator makes the liquid discharge in the first liquid reserve tank through the first solenoid valve of opening.

Optionally, install the second liquid reserve tank on the support body, the second liquid reserve tank with the infusion pipeline is the intercommunication setting, the second liquid reserve tank with infusion pipeline intercommunication department is provided with the second solenoid valve, the second liquid reserve tank with the liquid outlet pipeline is the intercommunication setting, the second liquid reserve tank with liquid outlet pipeline intercommunication department is provided with the third solenoid valve, second liquid reserve tank inner wall is fixed with the second electrothermal tube, second liquid reserve tank inner wall is fixed with second temperature sensor, second temperature sensor with multiple spot temperature recorder electricity is connected, be provided with refrigeration subassembly on the second liquid reserve tank.

When the temperature stability of thirty-five degrees and twenty-five degrees are required to be tested when the temperature stability of the water temperature of the toilet bowl is required to be tested, when an operator only needs to perform the temperature rise test on the first liquid storage tank, the temperature of the first liquid storage tank needs to be tested after the temperature of the first liquid storage tank is reduced from thirty-five degrees to twenty-five degrees, or the temperature of the first liquid storage tank needs to be tested after the temperature of the first liquid storage tank is increased from twenty-five degrees to thirty-five degrees, the efficiency is low at the moment, and the reference comparison is inconvenient in unit time.

Optionally, the refrigeration subassembly is including setting up the refrigerator in the support body outside, setting up the water pump in the support body outside, the second liquid reserve tank with the refrigerator is the intercommunication setting, the second liquid reserve tank with refrigerator intercommunication department is provided with the fifth solenoid valve, the second liquid reserve tank with the water pump is the intercommunication setting, the water pump with the refrigerator is the intercommunication setting.

Through adopting above-mentioned technical scheme, when the operator need cool down to the interior liquid temperature of second liquid reserve tank, the operator opens the fifth solenoid valve and inputes the interior liquid of second liquid reserve tank to the refrigerator in, later the operator pumps the interior liquid of refrigerator into the second liquid reserve tank through the water pump, accomplishes the interior liquid temperature decline operation of second liquid reserve tank.

Optionally, install the third liquid reserve tank on the support body, the third liquid reserve tank with the infusion pipeline is the intercommunication setting, the third liquid reserve tank with infusion pipeline intercommunication department is provided with the sixth solenoid valve, the third liquid reserve tank with the liquid outlet pipeline is the intercommunication setting, the third liquid reserve tank with the refrigerator is the intercommunication setting, the third liquid reserve tank with refrigerator intercommunication department is provided with the seventh solenoid valve, third liquid reserve tank inner wall is fixed with third temperature sensor, third temperature sensor with multiple spot temperature recorder electricity is connected.

In actual operation, the system temperature refrigeration effect test is usually accompanied when the intelligent closestool is tested for heating stability, because the second liquid storage tank contains interference factors such as a second electric heating tube, the third liquid storage tank is independently connected with the refrigerator, by adopting the technical scheme, when an operator needs to detect the refrigeration effect of the system, the operator supplies liquid to the third liquid storage tank through an external waterway and opens the sixth electromagnetic valve, so that the liquid flows into the third liquid storage tank, then the operator makes the liquid in the refrigerator flow into the refrigerator through the seventh electromagnetic valve, then the operator makes the liquid in the refrigerator flow into the third liquid storage tank through the second water pump, at this time, the temperature sensor transmits the liquid temperature in the third liquid storage tank to the multi-point temperature recorder, the operator records the data at this time, and after a plurality of tests, the average value of measured data is calculated so as to evaluate the refrigeration effect of the system.

Optionally, overflow pipelines are respectively arranged on the side walls of the first liquid storage tank, the second liquid storage tank and the third liquid storage tank.

Through adopting above-mentioned technical scheme, when liquid in first liquid reserve tank, second liquid reserve tank or the third liquid reserve tank exceeds appointed water level, unnecessary liquid can flow to appointed place through overflow pipeline.

Optionally, a rotating wheel is arranged on one side of the frame body, which is close to the ground.

Through adopting above-mentioned technical scheme, when the operator need shift the support body to other positions, the operator makes the support body slide to appointed place through promoting the support body.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when an operator needs to use the intelligent closestool temperature rise performance testing, the operator needs to infuse the first liquid storage tank through the infusion assembly, then the operator heats the liquid in the first liquid storage tank through the heating element, the temperature sensor transmits the temperature of the liquid in the first liquid storage tank to the multipoint temperature recorder in real time, when the temperature displayed by the multipoint temperature recorder is the designated temperature, the operator records the current recording time of the multipoint temperature recorder, the heating performance of the heating element is tested, the operator discharges the liquid in the first liquid storage tank in the designated time through the liquid outlet element, then the operator measures the residual liquid in the first liquid storage tank through the temperature sensor, and the multipoint temperature recorder checks whether the liquid in the first liquid storage tank is still at the designated temperature value, so that the heating stability of the heating element is tested, the test is repeated for a plurality of times, the temperature rise performance and the heating stability of the heating element are measured, and the heating stability of the heating element is convenient for the operator to test the heating stability of the heating element.

2. When an operator needs to heat the liquid in the first liquid storage tank, the operator heats the liquid in the first liquid storage tank through the first electric heating tube, and then the temperature sensor is used for measuring whether the surface of the liquid reaches a specified temperature value.

3. When the operator needs to cool the temperature of the liquid in the second liquid storage tank, the operator inputs the liquid in the second liquid storage tank into the refrigerator through the fifth electromagnetic, and then the operator pumps the liquid in the refrigerator into the second liquid storage tank through the water pump, so that the temperature of the liquid in the second liquid storage tank is lowered.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present application;

FIG. 2 is a schematic diagram of the overall structure of the embodiment of the present application, mainly for showing the structures of the third solenoid valve and the sixth solenoid valve;

fig. 3 is a schematic overall structure of an embodiment of the present application, mainly used for showing the internal structures of the first tank and the third tank;

FIG. 4 is a schematic diagram of the internal structure of a second tank according to an embodiment of the present application;

FIG. 5 is a schematic view of the structure of FIG. 4 at A;

fig. 6 is a schematic structural view of the transfer wheel in the present embodiment.

Reference numerals: 1. a frame body; 2. a first reservoir; 3. a first electric heating tube; 4. a first temperature sensor; 5. a multi-point temperature recorder; 6. an infusion assembly; 61. an infusion tube; 62. a first electromagnetic valve; 7. a liquid discharge assembly; 71. a liquid outlet pipe; 72. a second electromagnetic valve; 8. a second liquid storage tank; 9. a third electromagnetic valve; 10. a fourth electromagnetic valve; 20. a second electric heating tube; 30. a second temperature sensor; 40. a refrigeration assembly; 401. a refrigerator; 402. a water pump; 50. a fifth electromagnetic valve; 60. a third liquid storage tank; 70. a sixth electromagnetic valve; 80. a seventh electromagnetic valve; 90. a third temperature sensor; 100. an overflow pipe; 110. a rotating wheel; 120. and an eighth electromagnetic valve.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-6.

The embodiment of the application discloses an intelligent closestool heating stability test system.

Referring to fig. 1, an intelligent closestool heating stability test system, which comprises a frame body 1, install first liquid reserve tank 2 on the frame body 1, install second liquid reserve tank 8 on the frame body 1, still install third liquid reserve tank 60 on the frame body 1, be provided with refrigeration subassembly 40 on the second liquid reserve tank 8, refrigeration subassembly 40 includes refrigerator 401 and water pump 402, refrigerator 401 passes through the pipeline and communicates with second liquid reserve tank 8, water pump 402 one end inlet passes through the pipeline and is connected with refrigerator 401, water pump 402 liquid outlet passes through the pipeline and is connected with second liquid reserve tank 8, refrigerator 401 sets up to traditional industrial cold water machine, second liquid reserve tank 8 is fixed with fifth solenoid valve 50 with refrigerator 401 intercommunication department, third liquid reserve tank 60 passes through the pipeline and is connected with refrigerator 401, third liquid reserve tank 60 is fixed with eighth solenoid valve 120 with refrigerator 401 intercommunication department. In actual operation, the operator needs to perform a comparison test on the heating stability of the heating component, for example, the operator needs to perform a comparison test on the water temperature stability of thirty-five degrees, twenty-five degrees and five degrees, and the operator can perform a comparison test on the water temperature stability of the three water tanks at different temperatures.

Referring to fig. 1, in actual operation, an operator opens the fifth electromagnetic valve 50 through the external PLC device to make the liquid in the second liquid storage tank 8 flow into the refrigerator 401, and opens the eighth electromagnetic valve 120 through the external PLC device to make the third liquid storage tank 60 inject the liquid into the refrigerator 401, and then the operator returns the liquid in the refrigerator 401 to the second liquid storage tank 8 and the third liquid storage tank 60 through the water pump 402.

Referring to fig. 2, an infusion assembly 6 is disposed on the first liquid storage tank 2, the infusion assembly 6 includes an infusion pipeline 61 and a first electromagnetic valve 62, the infusion pipeline 61 is communicated with the first liquid storage tank 2, the first electromagnetic valve 62 is fixed at the communication position of the first liquid storage tank 2 and the infusion pipeline 61, the second liquid storage tank 8 and the third liquid storage tank 60 are also communicated with the infusion pipeline 61, the third electromagnetic valve 9 is fixed at the communication position of the second liquid storage tank 8 and the infusion pipeline 61, the sixth electromagnetic valve 70 is fixed at the communication position of the third liquid storage tank 60 and the infusion pipeline 61, and the infusion pipeline 61 is far away from one end of the first liquid storage tank 2 and is communicated with an external waterway. In actual operation, when the operator needs to inject water into the first liquid storage tank 2, the second liquid storage tank 8 and the third liquid storage tank 60, the operator injects liquid into the infusion pipeline 61 through the external water source, and controls the first electromagnetic valve 62, the third electromagnetic valve 9 and the fifth electromagnetic valve 50 to be opened through the external PLC device, so that the first liquid storage tank 2, the second liquid storage tank 8 and the third liquid storage tank 60 are filled with liquid.

Referring to fig. 3, a drain assembly 7 is disposed on the first liquid storage tank 2, the drain assembly 7 includes a liquid outlet pipe 71 and a second electromagnetic valve 72, one end of the liquid outlet pipe 71 is connected to the first liquid storage tank 2, and the other end is connected to a water inlet of an external drain pump 402.

Referring to fig. 3, a multipoint temperature recorder 5 is fixed on the frame body 1, a heating element for driving liquid to heat is arranged in the first liquid storage tank 2, the heating element is arranged as a first electric heating tube 3, first temperature sensors 4 are fixed in the first liquid storage tank 2, the number of the first temperature sensors 4 is two, the two first temperature sensors 4 are vertically placed, and the first electric heating tube 3 is electrically connected with the multipoint temperature recorder 5.

Referring to fig. 1, 2 and 3, in actual operation, when an operator needs to test the heating stability of the first electrothermal tube 3 in the intelligent closestool, the operator inputs the liquid in the first liquid storage tank 2 to the position of the first temperature sensor 4 far away from the bottom wall of the first liquid storage tank 2, then the operator heats the liquid in the first liquid storage tank 2 to a designated temperature, then the external PLC device opens the second electromagnetic valve 72 to drain the liquid in the first liquid storage tank 2, when the liquid level in the first liquid storage tank 2 reaches the first temperature sensor 4 near the bottom wall of the first liquid storage tank 2, the operator closes the second electromagnetic valve 72 to stop draining the liquid in the first liquid storage tank 2, then the first temperature sensor 4 transmits the temperature indication to the multipoint temperature recorder 5, the operator checks the temperature of the liquid in the first liquid storage tank 2 through the multipoint temperature recorder 5, and compares the temperature value with the designated temperature, then the operator repeats the above actions, and records the comparison results each time so as to know the heating performance of the first electrothermal tube 3.

Referring to fig. 3, a third liquid storage tank 60 is disposed in communication with the liquid outlet pipe 71, a seventh electromagnetic valve 80 is disposed at a position where the third liquid storage tank 60 is in communication with the liquid outlet pipe 71, and a third temperature sensor 90 is fixed to an inner wall of the third liquid storage tank 60. In actual operation, the system water temperature needs to be adjusted to a temperature comfortable to a human body, the refrigerator 401 needs to be used in the debugging process, an operator needs to test the refrigerating effect of the refrigerator 401, when the operator tests the refrigerating effect of the refrigerator 401, the operator inputs liquid into the infusion pipeline 61 through an external water source, the liquid flows into the third liquid storage tank 60 through the infusion pipeline 61, at the moment, the third temperature sensor 90 transmits liquid temperature information to the multipoint temperature recorder 5, the operator records the liquid temperature at the moment, then the operator opens the eighth electromagnetic valve 120, so that the liquid flows into the refrigerator 401 through the pipeline, then the operator pumps the liquid in the refrigerator 401 into the third liquid storage tank 60 through the water pump 402, at the moment, the third temperature sensor 90 transmits the liquid temperature in the third liquid storage tank 60 to the multipoint temperature recorder 5 in real time, the operator records the liquid temperature in the third liquid storage tank 60, and the operation is repeated, and the refrigerating effect of the refrigerator 401 is known after a plurality of tests.

Referring to fig. 3 and 4, a second electric heating tube 20 is fixed on the inner wall of the second liquid storage tank 8, the second electric heating tube 20 is electrically connected with the multipoint temperature recorder 5, a second temperature sensor 30 is fixed in the second liquid storage tank 8, the second liquid storage tank 8 is communicated with the liquid outlet pipeline 71, and a fifth electromagnetic valve 50 is fixed at the joint of the second liquid storage tank 8 and the liquid outlet pipeline 71.

Referring to fig. 3 and 4, in actual operation, when an operator needs to make a comparison test, if the operator needs to check the effect of the system temperature stability at thirty-five degrees and twenty-five degrees, the operator opens the first electromagnetic valve 62 and the third electromagnetic valve 9 through the external PLC device, then the operator injects liquid into the infusion pipeline 61 through the external water source, the liquid enters the first liquid storage tank 2 and the second liquid storage tank 8 through the infusion pipeline 61 respectively, then the operator heats the liquid in the first liquid storage tank 2 to thirty-five degrees through the first electrothermal tube 3, the operator heats the liquid in the second liquid storage tank 8 to twenty-five degrees through the second electrothermal tube 20, then the operator closes the first electromagnetic valve 62 and the third electromagnetic valve 9 through the external PLC device, and opens the second electromagnetic valve 72 and the fourth electromagnetic valve 10 through the external PLC device, so that the liquid in the first liquid storage tank 2 and the second liquid storage tank 8 flows out through the liquid outlet pipeline 71, when the specified time arrives, the operator records the liquid temperatures in the first liquid storage tank 2 and the second liquid storage tank 8 through the multi-point temperature recorder 5, and repeats the operation, the liquid storage is checked for multiple times, the system stability performance is checked through the second electrothermal tube 20, and the operator needs to make a multiple temperature adjustment test with the second electrothermal tube 401.

Referring to fig. 5, when the liquid overflows the first liquid storage tank 2 or the second liquid storage tank 8 or the third liquid storage tank 60, the liquid will flow to the laboratory ground, so that the laboratory ground is wet, in order to prevent the liquid from overflowing, so that the overflow pipeline 100 is fixed on the first liquid storage tank 2, the overflow pipeline 100 is communicated with the inner cavity of the first liquid storage tank 2, the inner cavity of the second liquid storage tank 8 and the inner cavity of the third liquid storage tank 60 are both communicated with the overflow pipeline 100, the rotating wheel 110 is arranged on the frame 1, in actual operation, when the operator needs to slide the frame 1 to the designated position, the operator pushes the frame 1, and under the action of the rotating wheel 110, the frame 1 can be quickly slid to the designated position.

The implementation principle of the intelligent closestool heating stability test system provided by the embodiment of the application is as follows: when an operator needs to test the heating stability of the intelligent closestool, the operator adds the liquid in the first liquid storage tank 2 to the position of the first temperature sensor 4 far away from the bottom wall of the first liquid storage tank 2 through an external waterway pipeline, then the operator heats the liquid in the first liquid storage tank 2 to a specified temperature through the first electric heating tube 3, data when the liquid is heated to the specified temperature is recorded, the operator is convenient to check the heating performance of the first electric heating tube 3, then the operator opens the second electromagnetic valve 72 through external PLC equipment, the liquid in the first liquid storage tank 2 is discharged to the position of the first temperature sensor 4 close to the bottom wall of the first liquid storage tank 2 in a specified time, then the operator checks the temperature of the liquid at the moment through the multi-point temperature recorder 5, the temperature drop value of the liquid at the moment is observed, the temperature drop value of the liquid is recorded, the operation is repeated, and the operator compares the recorded data after a plurality of tests to know the heating stability of the first electric heating tube 3.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (9)

1. An intelligent closestool heating stability test system, includes support body (1), its characterized in that: install first liquid reserve tank (2) on support body (1), be provided with the heating piece that is used for heating liquid in first liquid reserve tank (2), first liquid reserve tank (2) inner wall is fixed with a plurality of first temperature sensor (4), be fixed with multiple spot temperature recorder (5) on support body (1), first temperature sensor (4) with multiple spot temperature recorder (5) electricity is connected, be provided with on first liquid reserve tank (2) be used for to infusion set (6) of first liquid reserve tank (2) infusion, still be provided with on first liquid reserve tank (2) and be used for liquid exhaust flowing back subassembly (7).

2. The intelligent toilet bowl heat stability test system of claim 1, wherein: the heating piece is arranged to be a first electric heating tube (3), and the first electric heating tube (3) is fixed on the inner wall of the first liquid storage tank (2).

3. The intelligent toilet bowl heat stability test system of claim 1, wherein: the infusion assembly (6) comprises an infusion pipeline (61) connected to the first liquid storage tank (2), and a first electromagnetic valve (62) fixed at the communication position of the first liquid storage tank (2) and the infusion pipeline (61), wherein one end, far away from the first liquid storage tank (2), of the infusion pipeline (61) is communicated with an external waterway.

4. A smart toilet heating stability test system as recited in claim 3, wherein: the liquid draining assembly (7) comprises a liquid outlet pipeline (71) connected to the first liquid storage tank (2), and a second electromagnetic valve (72) fixed at the communication position of the first liquid storage tank (2) and the liquid outlet pipeline (71).

5. The intelligent toilet bowl heat stability test system of claim 4, wherein: install second liquid reserve tank (8) on support body (1), second liquid reserve tank (8) with infusion pipeline (61) are the intercommunication setting, second liquid reserve tank (8) with infusion pipeline (61) junction is provided with third solenoid valve (9), second liquid reserve tank (8) with go out liquid pipeline (71) and be the intercommunication setting, second liquid reserve tank (8) with go out liquid pipeline (71) junction and be provided with fourth solenoid valve (10), second liquid reserve tank (8) inner wall is fixed with second electrothermal tube (20), second liquid reserve tank (8) inner wall is fixed with second temperature sensor (30), second temperature sensor (30) with multiple spot temperature recorder (5) electricity is connected, be provided with refrigeration subassembly (40) on second liquid reserve tank (8).

6. The intelligent toilet bowl heat stability test system of claim 5, wherein: the refrigeration assembly (40) comprises a refrigerator (401) arranged on the outer side of the frame body (1), and a water pump (402) arranged on the outer side of the frame body (1), wherein the second liquid storage tank (8) is communicated with the refrigerator (401), a fifth electromagnetic valve (50) is arranged at the joint of the second liquid storage tank (8) and the refrigerator (401), the second liquid storage tank (8) is communicated with the water pump (402), and the water pump (402) is communicated with the refrigerator (401).

7. The intelligent toilet bowl heat stability test system of claim 6, wherein: install third liquid reserve tank (60) on support body (1), third liquid reserve tank (60) with infusion pipeline (61) are the intercommunication setting, third liquid reserve tank (60) with infusion pipeline (61) junction is provided with sixth solenoid valve (70), third liquid reserve tank (60) with liquid outlet pipe (71) are the intercommunication setting, third liquid reserve tank (60) with liquid outlet pipe (71) junction is provided with seventh solenoid valve (80), third liquid reserve tank (60) with refrigerator (401) are the intercommunication setting, third liquid reserve tank (60) with refrigerator (401) junction is provided with eighth solenoid valve (120), third liquid reserve tank (60) inner wall is fixed with third temperature sensor (90), third temperature sensor (90) with multiple spot temperature recorder (5) electricity is connected.

8. The intelligent toilet bowl heat stability test system of claim 7, wherein: be provided with on the support body (1) be used for first liquid reserve tank (2) second liquid reserve tank (8) with overflow pipeline (100) of liquid overflow in third liquid reserve tank (60), first liquid reserve tank (2) second liquid reserve tank (8) with third liquid reserve tank (60) all are the intercommunication setting with overflow pipeline (100).

9. The intelligent toilet bowl heat stability test system of claim 1, wherein: the rotating wheel (110) is arranged on one side, close to the ground, of the frame body (1).

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