CN214048682U - Water tank assembly and robot - Google Patents

Abstract

The utility model relates to the technical field of robot, a water tank set spare and robot is disclosed. The water tank subassembly includes the water tank, first electrode spare, the second electrode spare, sampling circuit and controller, the water tank is including acceping the chamber, first electrode spare and second electrode spare are all installed in acceping the chamber, the second electrode spare has vertical difference in height with first electrode spare, sampling circuit is connected with first electrode spare electricity, the controller respectively with first electrode spare, second electrode spare and sampling circuit electricity are connected, be arranged in selecting one of them electrode spare output level signal in first electrode spare and the second electrode spare, so that first electrode spare, liquid, second electrode spare and sampling circuit can form the detection return circuit. Compared with the traditional mode, the water tank assembly needs to be provided with a complex floating ball water level detection structure, and the water tank assembly can realize the detection of the liquid level state only through two electrode pieces and a peripheral simple circuit, so that the detection structure adopted by the water tank assembly is simpler and more scientific, and the detection cost is reduced.

Description

Water tank assembly and robot

Technical Field

The utility model relates to the technical field of robot, concretely relates to water tank set spare and robot.

Background

With the development of the robot technology, the sweeping robot is also increasingly popularized, the sweeping robot enters thousands of households, and some sweeping robots are provided with a floor mopping function, so that two operation functions of sweeping and mopping can be realized. In order to reliably ensure that the floor sweeping robot can implement the floor mopping function, the floor sweeping robot needs to monitor the liquid level state of the water tank in real time so as to ensure that the water tank stores enough water to normally complete the work.

The traditional robot adopts the water level detection structure with the floating ball to detect the liquid level state of the water tank, but the detection structure is more complex and the cost is higher.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the utility model is to provide a water tank assembly and robot, it detects the simple science of structure.

In a first aspect, an embodiment of the present invention provides a water tank assembly, including:

a water tank including a receiving chamber for storing liquid;

the first electrode piece is arranged in the accommodating cavity;

the second electrode piece is arranged in the accommodating cavity, and a vertical height difference is formed between the second electrode piece and the first electrode piece;

the sampling circuit is electrically connected with the first electrode element;

the controller, respectively with first electrode spare the second electrode spare reaches the sampling circuit electricity is connected, is used for selecting first electrode spare with one of them electrode spare output level signal in the second electrode spare, so that first electrode spare, save in the liquid of water tank the second electrode spare reaches the sampling circuit can form the detection return circuit.

Optionally, in the detection circuit, an initial on position of the first pole element and the second pole element is located at the bottom of the water tank.

Optionally, the first electrode is disposed at the bottom of the water tank, the second electrode is disposed at the top of the water tank, and one end of the second electrode extends towards the bottom of the water tank in a bending manner.

Optionally, the second pole element comprises:

one end of the first straight line part penetrates through the water tank and extends into the accommodating cavity, and the other end of the first straight line part is positioned outside the accommodating cavity;

one end of the first bending part is connected with one end of the first straight line part, and the other end of the first bending part extends towards the bottom of the water tank in a bending mode.

Optionally, in the detection circuit, an initial on position of the first pole element and the second pole element is located at the top of the water tank.

Optionally, the first electrode is disposed at the bottom of the water tank, one end of the first electrode extends towards the top of the water tank in a bending manner, and the second electrode is disposed at the top of the water tank.

Optionally, the water tank assembly further comprises a partition plate, the partition plate is vertically installed in the accommodating cavity to divide the accommodating cavity into a liquid cabin and an isolation cabin, and one end of the first electrode piece and one end of the second electrode piece both penetrate through the partition plate and then extend to the liquid cabin.

Optionally, the water tank assembly further includes a line detection circuit disposed in the isolation bin, and the line detection circuit is electrically connected between the first electrode member and the second electrode member.

Optionally, the line detection circuit includes a diode, and an anode of the diode is electrically connected to the first electrode element and a cathode of the diode is electrically connected to the second electrode element.

In a second aspect, an embodiment of the present invention provides a robot, including the above water tank assembly.

Compared with the prior art, the utility model following beneficial effect has at least: the embodiment of the utility model provides an among the water tank set spare, the water tank is including the chamber of acceping that is used for saving liquid, first electrode spare is installed in acceping the chamber, the second electrode spare has vertical difference in height with first electrode spare, sampling circuit is connected with first electrode spare electricity, the controller respectively with first electrode spare, second electrode spare and sampling circuit electricity are connected, be arranged in selecting one of them electrode spare output level signal in first electrode spare and the second electrode spare, so that first electrode spare, save in the liquid of water tank, second electrode spare and sampling circuit can form the detection return circuit. Compared with the traditional mode, the water tank assembly needs to be provided with a complex floating ball water level detection structure, and the water tank assembly can realize the detection of the liquid level state only through two electrode pieces and a peripheral simple circuit, so that the detection structure adopted by the water tank assembly is simpler and more scientific, and the detection cost is reduced.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the figures in which like reference numerals refer to similar elements and which are not to scale unless otherwise specified.

Fig. 1 is a schematic structural diagram of a robot according to an embodiment of the present invention;

fig. 2 is an exploded schematic view of a robot according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a water tank assembly according to an embodiment of the present invention, wherein a controller can detect a water state or a water-free state of the water tank assembly;

FIG. 4 is another schematic structural view of the water tank assembly shown in FIG. 1, wherein the controller can detect a water condition or a water-out condition of the water tank assembly;

FIG. 5 is an equivalent circuit diagram of FIG. 4;

fig. 6 is a schematic structural diagram of another water tank assembly according to an embodiment of the present invention, in which a controller can detect whether the water tank assembly is in a water-filled state or a water-free state;

fig. 7 is a schematic structural diagram of another water tank assembly according to an embodiment of the present invention, wherein a controller can detect a full state or a not full state of the water tank assembly;

fig. 8 is a schematic structural diagram of another water tank assembly according to an embodiment of the present invention, wherein a controller can detect a full state or a not full state of the water tank assembly;

fig. 9 is a schematic structural view of another water tank assembly according to an embodiment of the present invention, in which the accommodating chamber is divided into a liquid chamber and an isolation chamber;

fig. 10 is a schematic structural diagram of another water tank assembly according to an embodiment of the present invention, in which the water tank assembly further includes a line detection circuit.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if there is no conflict, various features in the embodiments of the present invention may be combined with each other, and all of them are within the scope of the present invention. Additionally, while functional block divisions are performed in apparatus schematics, with logical sequences shown in flowcharts, in some cases, steps shown or described may be performed in sequences other than block divisions in apparatus or flowcharts. Furthermore, the words "first", "second", "third", etc. used in the present invention do not limit the data and execution order, but only distinguish the same items or similar items having substantially the same function and action.

Referring to fig. 1 and 2, the robot 100 includes a main body 200, a cleaning assembly 300, a collecting assembly 400, a water tank assembly 500, and a front impact 600.

The robot 100 may include a scrubber, a mopping machine, a sweeping robot, and the like. Therein, the robot 100 may be configured in any shape, which can travel on a floor, a carpet, or the like surface in order to clean dirt of the corresponding surface. As shown in fig. 1, the robot 100 is configured in a circular truncated cone-like shape.

It is understood that the robot 100 may be configured with an automatic navigation and obstacle avoidance function, which automatically navigates to complete a cleaning work during a cleaning travel and meets an obstacle during the cleaning, and also automatically avoids the obstacle from colliding with the obstacle.

The fuselage 200 is equipped with trench 20a, and water tank assembly 500 detachably installs in trench 20a, for example, fuselage 200 is equipped with a plurality of screens, and water tank assembly 500 is equipped with a plurality of lugs, when needs install water tank assembly 500 in trench 20a, only need aim at the screens of fuselage 200 with water tank assembly 500's lug and buckle in the screens to install water tank assembly 500 in trench 20 a. Because both the water tank assembly 500 and the body 200 are detachably mounted, the user can replace or update the water tank assembly 500 at any time, and the user experience is improved.

In the present embodiment, the slot 20a is provided in the middle of the body 200, and when the water tank assembly 500 is installed in the body 200, the body 200 embraces the water tank assembly 500, so that the water tank assembly 500 can be reliably fixed in the body 200 while the body 200 is moved.

The cleaning assembly 300 is mounted to the main body 200 and is driven by the main body 200 to perform cleaning. The cleaning assembly 300 may be constructed of any suitable construction of cleaning elements and may perform the cleaning operation using any suitable cleaning method.

The collection assembly 400 is provided with a sewage outlet, and the collection assembly 400 is installed between the body 200 and the drum 32 and abuts against the drum 32 for collecting and separating the garbage and the sewage carried by the cleaning assembly 300.

The water tank assembly 500 is provided with a sewage inlet, and when the water tank assembly 500 is installed in the slot 20a, the sewage inlet is communicated with the sewage outlet, and sewage can flow into the water tank assembly 500 through the sewage outlet and the sewage inlet. The sewage may be naturally guided into the water tank assembly 500, or may flow into the water tank assembly 500 by other acting forces, for example, the body 200 is provided with a fan, the fan generates wind force, and the sewage is sucked into the water tank assembly 500 through the sewage outlet and the sewage inlet under the action of the wind force.

The front crash 600 is detachably mounted to the main body 200, and the cleaning assembly 300 is located between the main body 200 and the front crash 600. When the robot 100 encounters an obstacle during traveling, the front collision 600 can effectively buffer the collision between the cleaning assembly 300 and the obstacle, and can better and effectively protect the cleaning assembly 300 and the body 200.

In some embodiments, referring to fig. 3, the water tank assembly 500 includes a water tank 51, a first electrode 52, a second electrode 53, a sampling circuit 54, and a controller 55.

The tank 51 includes a housing 510 for storing a liquid, including water or other fluid.

The first electrode 52 is installed in the receiving cavity 510, the second electrode 53 is installed in the receiving cavity 510, and the second electrode 53 is spaced from the first electrode 52 by a predetermined distance.

In some embodiments, the first electrode element 52 and the second electrode element 53 may be integrally mounted in the receiving cavity 510.

In some embodiments, the first electrode 52 and the second electrode 53 may also be partially installed in the receiving cavity 510, for example, one end of the first electrode 52 extends through the water tank 51 to the inside of the receiving cavity 510, and the other end of the first electrode 52 is located outside the receiving cavity 510, and similarly, one end of the second electrode 53 extends through the water tank 51 to the inside of the receiving cavity 510, and the other end of the second electrode 53 is located outside the receiving cavity 510. By adopting the installation mode, the wiring of the electrode element can be completed outside the accommodating cavity 510 without excessive anti-creeping treatment, so that the structure is favorable for wiring.

In the present embodiment, the first electrode 52 and the second electrode 53 have a vertical height difference, and the vertical height difference means that the first electrode 52 and the second electrode 53 are spaced apart from each other by a preset distance in a vertical direction, and there is a height difference therebetween. When the height of the liquid in the receiving cavity 510 is sufficient to cover the vertical height difference, the first pole element 52 is indirectly connected with the second pole element 53 through the liquid.

The sampling circuit 54 is electrically connected to the first electrode member 52. in some embodiments, the sampling circuit 54 can be mounted inside the housing 510 or can be mounted outside the housing 510. The sampling circuit 54 can reliably sample the voltage without excessive leakage protection when mounted outside the housing 510.

The controller 55 is electrically connected to the first electrode 52, the second electrode 53, and the sampling circuit 54. In this embodiment, the controller 55 may select one of the first electrode 52 and the second electrode 53 to output a level signal, so that the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 form a detection circuit 56, and the sampling circuit 54 generates a sampling voltage.

It is understood that the level signal may be high or low.

It will be appreciated that when the receiving chamber 510 is filled with a sufficient amount of liquid, and one of the first pole element 52 and the second pole element 53 outputs a level signal, the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 form the detection circuit 56, the level signal will cause the sampling circuit 54 to generate a larger sampling voltage when the level signal flows in the detection circuit.

When the receiving cavity 510 does not store enough liquid, for example, the receiving cavity 510 is used up, or the receiving cavity 510 does not store enough liquid to connect the first electrode 52 and the second electrode 53 for the first time, so that even if one of the first electrode 52 and the second electrode 53 outputs a level signal, the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 cannot form the detection circuit 56, and the sampling voltage of the sampling circuit 54 is less than or equal to the minimum voltage threshold, for example, the minimum voltage threshold is 0 v.

As can be seen from the above, whether the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 can form the detection circuit 56 or not, the sampling voltage can be represented by a corresponding value to indicate whether the detection circuit 56 is formed or not, for example, the sampling voltage can be 0 v, close to 0 v or greater than a preset voltage threshold.

In some embodiments, the sampling circuit 54 may be implemented by any suitable discrete device, for example, the sampling circuit 54 is a resistor network formed by a resistor or several resistors, and referring to fig. 4, the sampling circuit 54 is a resistor R1. In some embodiments, the sampling circuit 54 may also be a circuit composed of resistors and capacitors with various numbers, and may further be composed of discrete devices such as resistors, capacitors, and electronic switching tubes, which are not described herein.

Generally, the controller 55 is configured with various functional pins, such as an I/O pin and an ADC analog-to-digital pin, the controller 55 is electrically connected to the first pole element 52 through the ADC analog-to-digital pin, and the controller 55 is electrically connected to the second pole element 53 through the I/O pin.

Referring to fig. 4, in some embodiments, a resistor R2 is disposed between the ADC module pin and the first electrode 52, a resistor R3 is disposed between the I/O pin and the second electrode 53, and both the resistor R2 and the resistor R3 can perform a current limiting protection function.

In some embodiments, the controller 55 sets the I/O pin to be in a high state and sets the ADC module pin to be in a low state, or the controller 55 sets the I/O pin to be in a high state all the time and sets the ADC module pin to be switched from a high-impedance state to a low state, the controller 55 can select the second electrode 53 to output a high level through the I/O pin, and the sampling circuit 54 generates a larger sampling voltage when the receiving cavity 510 stores a sufficient amount of liquid and the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 form the detection loop 56. When the receiving cavity 510 does not store a sufficient amount of liquid and the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 are not able to form the detection circuit 56, the sampling voltage is small.

In some embodiments, the controller 55 sets the I/O pin to be in a low state and sets the ADC module pin to be in a high state, or the controller 55 sets the I/O pin to be switched from a high-impedance state to a low state, sets the ADC module pin to be continuously in the high state, and the controller 55 can select the first electrode 52 to output a high level through the ADC module pin, and the sampling circuit 54 generates a larger sampling voltage when the receiving cavity 510 stores a sufficient amount of liquid and the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 form the detection loop 56. When the receiving cavity 510 does not store a sufficient amount of liquid and the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 are not able to form the detection circuit 56, the sampling voltage is small.

In the present embodiment, the controller 55 obtains the sampling voltage of the sampling circuit 54, and determines the liquid level state of the water tank 51 based on the sampling voltage.

Referring to fig. 5, when the liquid is water, the water has a larger resistance R4 because the water has a certain conductivity but a lower conductivity. When the water in the housing 51 is sufficient to indirectly communicate the first electrode 52 and the second electrode 53, the controller 55 may select the second electrode 53 to output a high level through the I/O pin, the high level is transmitted to the first electrode 52 through the water, and then through the resistors R1 and GND of the sampling circuit 54, so that the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 form the detection loop 56, and at this time, the sampling voltage VDD R1/(R1+ R4) is obtained, so that the controller 55 may determine the liquid level state of the water tank 51 according to the sampling voltage.

Generally speaking, need set up comparatively complicated floater water level detection structure relatively traditional mode, the water tank set spare only through two electrode components and peripheral simple circuit alright with the detection that realizes the liquid level state, consequently, the detection structure that the water tank set spare adopted is fairly simple scientific to reduce and detect the cost.

In some embodiments, the liquid level state includes a water state and a no water state, the water state refers to that the water level height of the liquid capacity in the water tank is greater than or equal to the minimum water level height, and the no water state refers to that the liquid capacity in the water tank is less than the minimum water level height, it can be understood that the minimum water level height is customized by a user, for example, the minimum water level height is that the water level is 2 cm, 3 cm, 5 cm, and the like.

In order to detect the water state or the water-free state, in some embodiments, in the detection circuit 56, the initial connection position of the first electrode 52 and the second electrode 53 is located at the bottom of the water tank 51, where the initial connection position refers to a position at which the first electrode 52 and the second electrode 53 are connected by the liquid, in this embodiment, the first electrode 52 and the second electrode 53 are connected by the liquid at the bottom of the water tank 51 for the first time, for example, the liquid gradually rises from the bottom of the water tank 51, when the liquid rises, the liquid first connects the first electrode 52 and the second electrode 53, when the liquid level reaches a certain height when the liquid continues to rise, the liquid continuously connects the first electrode 52 and the second electrode 53, and the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 can form the detection circuit 56, therefore, the sampling voltage may be relatively large.

In some embodiments, the initial turn-on position is equal to the lowest water level, and when the first pole element 52 and the second pole element 53 cannot be turned on for the first time by any liquid, the water level of the liquid volume of the water tank 51 is lower than the lowest water level, and the sampling voltage is smaller because the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 cannot form the detection loop 56.

In some embodiments, when the controller 55 determines the liquid level state of the water tank 51 according to the sampling voltage, first, the controller 55 determines whether the sampling voltage is greater than or equal to a preset voltage threshold, if so, the liquid level state of the water tank 51 is determined to be a water state, and if not, the liquid level state of the water tank 51 is determined to be a water-free state. As mentioned above, since the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 can form the detection circuit 56, the sampling voltage is larger, and therefore, the sampling voltage is greater than or equal to the preset voltage threshold, which indicates that the water level height of the current liquid volume is at least greater than or equal to the minimum water level height, and the current liquid volume is sufficient for the robot to complete the operation.

Similarly, since the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 are not able to form the detection circuit 56, the sampling voltage is relatively small, and therefore, if the sampling voltage is smaller than the preset voltage threshold, it indicates that the water level height of the current liquid volume is smaller than the minimum water level height, and the current liquid volume cannot meet the requirement of the robot for completing the operation.

Referring to fig. 5, the controller 55 detects the sampling voltage of the resistor R1 through the ADC analog-to-digital pin, and when the water level is higher than the end of the second pole element 53 close to the first pole element 52, the controller 55 determines that the sampling voltage of the detecting resistor R1 is greater than 0, and determines that the liquid level state is the water-containing state. When the water level is lower than the end of the second pole element 53 close to the first pole element 52, the controller 55 determines that the liquid level state is the no-water state if the sampled voltage of the detection resistor R1 is equal to or close to 0. In some embodiments, the resistor R1 may be set to a larger resistance value for more reliable and accurate determination of the fluid level condition.

Referring to fig. 4, in some embodiments, the first electrode 52 is disposed at the bottom of the water tank 51, and the second electrode 53 is disposed at the top of the water tank 51 and has one end bent and extended toward the bottom of the water tank 51, such that the initial connection position of the first electrode 52 and the second electrode 53 is located at the bottom of the water tank 51.

It is understood that the first electrode 52 may have any suitable shape, and the second electrode 53 may also have any curved shape, for example, the first electrode 52 is linear, and the second electrode 53 is folded, wherein the second electrode 53 includes a first linear portion 531 and a first bent portion 532, and one end of the first linear portion 531 passes through the water tank 51 and extends into the receiving cavity 510, and then is connected to one end of the first bent portion 532. The other end of the first straight portion 531 is located outside the receiving cavity 510, and the other end of the first bent portion 532 bends and extends toward the bottom of the water tank 51 to continuously approach the first electrode 52.

It will also be appreciated that the second pole element 53 may also be curved, wavy or otherwise irregularly curved.

Referring to fig. 6, in some embodiments, the first pole piece 52 and the second pole piece 53 are both disposed at the bottom of the water tank 51, and the initial connecting position of the two pole pieces is located at the bottom of the water tank 51. As shown in fig. 5, the first electrode member 52 and the second electrode member 53 are both linear. It is understood that the first pole element 52 and the second pole element 53 may have any shape as long as the initial connection position of the first pole element 52 and the second pole element 53 is located at the bottom of the water tank 51, and the shape of the first pole element 52 and the second pole element 53 is not limited thereto.

With the above structure, it is possible to reliably and scientifically detect whether the liquid level state of the water tank 51 is in a water-containing state or a water-free state.

In some embodiments, the tank assembly 500 may also detect whether the fluid level condition is a full condition or an underfill condition. Referring to fig. 7, in the detection circuit 56, the initial connection position of the first pole element 52 and the second pole element 53 is located at the top of the water tank 51.

In the embodiment, the first electrode 52 and the second electrode 53 are first connected to the liquid at the top of the water tank 51, for example, the liquid gradually rises from the bottom of the water tank 51, when the liquid level rises, the first electrode 52 and the second electrode 53 are first connected to the liquid, when the liquid level reaches a certain height while the liquid continues to rise, the first electrode 52 and the second electrode 53 are continuously connected to the liquid, and the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 can form the detection loop 56, so the sampling voltage is relatively large.

If the liquid is not stored enough to switch the first pole element 52 to the second pole element 53 for the first time, the level state of the liquid in the tank 51 is not full.

In some embodiments, the initial turn-on position is equal to the maximum water level, and when the first pole element 52 and the second pole element 53 cannot be turned on for the first time by any liquid, the water level of the liquid volume of the water tank 51 is lower than the maximum water level, and the sampling voltage is smaller because the first pole element 52, the liquid, the second pole element 53 and the sampling circuit 54 cannot form the detection loop 56.

In some embodiments, when the controller 55 determines the liquid level state of the water tank 51 according to the sampling voltage, the controller 55 determines whether the sampling voltage is greater than or equal to a preset voltage threshold, if so, determines that the liquid level state of the water tank 51 is a full state, and if not, determines that the liquid level state of the water tank 51 is an under state. As mentioned above, since the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 can form the detection circuit 56, the sampling voltage is larger, and therefore, the sampling voltage is larger than or equal to the preset voltage threshold, which indicates that the water level height of the current liquid volume is at least larger than or equal to the highest water level height, and the current liquid volume is full and no liquid needs to be stored.

Similarly, since the first electrode 52, the liquid, the second electrode 53 and the sampling circuit 54 are not able to form the detection circuit 56, the sampling voltage is relatively small, and therefore, if the sampling voltage is smaller than the preset voltage threshold, it indicates that the water level height of the current liquid volume is smaller than the maximum water level height, and the liquid can be added to the water tank 51.

Referring to fig. 7, in some embodiments, the first electrode 52 is disposed at the bottom of the water tank 51 and one end of the first electrode is bent and extended toward the top of the water tank 51, and the second electrode 53 is disposed at the top of the water tank 51, such that the initial connection position of the first electrode 52 and the second electrode 53 is located at the top of the water tank 51.

It is understood that the second electrode 53 may have any suitable shape, and the first electrode 52 may also have any curved shape, for example, the second electrode 53 is linear, and the first electrode 52 is folded, wherein the first electrode 52 includes a second linear portion 521 and a second bent portion 522, and one end of the second linear portion 521 passes through the water tank 51 and extends into the receiving cavity 510, and then is connected to one end of the second bent portion 522. The other end of the second straight portion 521 is located outside the receiving cavity 510, and the other end of the second bent portion 522 is curved and extends towards the top of the water tank 51 and continuously approaches the second pole element 53.

It will also be appreciated that the first pole element 52 may also be curved, wavy or otherwise irregularly curved.

Referring to fig. 8, in some embodiments, the first pole piece 52 and the second pole piece 53 are both disposed on the top of the water tank 51, and the initial connecting position of the two pole pieces is located on the top of the water tank 51. As shown in fig. 7, the first electrode member 52 and the second electrode member 53 are both linear. It is understood that the first pole element 52 and the second pole element 53 may have any shape as long as the initial connection position of the first pole element 52 and the second pole element 53 is located at the top of the water tank 51, and the shape of the first pole element 52 and the second pole element 53 is not limited thereto.

With the above structure, it is possible to reliably and scientifically detect whether the liquid level state of the water tank 51 is the full state or the underfill state.

In general, the water tank assembly 500 may be installed in the robot 100 as a whole, in order to facilitate installation of the water tank assembly 500 and to protect the first electrode 52, the second electrode 53 and the circuit from electric leakage, in some embodiments, referring to fig. 9, the water tank assembly 500 further includes a partition 57, the partition 57 is vertically installed in the accommodating cavity 510 to divide the accommodating cavity 510 into a liquid chamber 511 and an isolation chamber 512, and one end of the first electrode 52 and one end of the second electrode 53 both extend to the liquid chamber 511 after passing through the partition 57. Therefore, with this structure, on one hand, it is possible to install the respective lines, the first pole member 52 and the second pole member 53 in the water tank assembly 500 to form a whole, and it is not necessary to install the water tank assembly and then lap the respective lines in the subsequent installation. On the other hand, it can effectively protect the first electrode 52, the second electrode 53 and the circuit from leakage, so that the water tank assembly 500 operates more reliably.

In general, each electrode and each line in the water tank assembly are in contact with liquid, and therefore, the water tank assembly is easily corroded or damaged by the liquid after being used for a long time, and other abnormal conditions such as the electrode being damaged or the line being broken easily occur. And, the water tank set spare among the robot generally requires sealed, in case the water tank set spare shaping, the water tank set spare will hardly be opened, opens the water tank set spare, and to a great extent means scrapping of water tank set spare. When the sampling voltage of the water tank assembly cannot be detected, the liquid level state may be actually in a non-water state or a non-full state, or other lines or electrode elements may be damaged, so that in some embodiments, the operational reliability of the water tank assembly may be detected without physically damaging the water tank assembly.

Referring to fig. 10, in some embodiments, the water tank assembly 500 further includes a line detection circuit 58, the line detection circuit 58 is disposed in the isolation chamber 512, and the line detection circuit 58 is electrically connected between the first electrode 52 and the second electrode 53. When the liquid level state is a non-water state or a low-full state, the controller 55 selects the other one of the first pole element 52 and the second pole element 53 to output a high level, so that the first pole element 52, the line detection circuit 58 and the second pole element 53 can form a loop 59. Then, the controller 55 detects a target level signal of one of the pole members, and repeatedly determines the liquid level state of the water tank 51 based on the target level signal.

For example, when the liquid level state is detected, the controller 55 sets the I/O pin to be in a high level state and sets the ADC analog-to-digital pin to be in a low level state, or the controller 55 sets the I/O pin to be continuously in the high level state all the time and sets the ADC analog-to-digital pin to be switched from a high resistance state to a low level state, the controller 55 may select the second electrode 53 through the I/O pin to output the high level, since the liquid is not enough to first connect the first electrode 52 and the second electrode 53, the sampling voltage is 0, and then the controller 55 preliminarily determines that the liquid level state is in a non-water state or a non-full state.

Considering that the sampling voltage is 0 due to the abnormality of the line or the electrode, the controller 55 sets the I/O pin to be in a low level state and sets the ADC analog-to-digital pin to be in a high level state, or the controller 55 sets the I/O pin to be switched from a high resistance state to a low level state and sets the ADC analog-to-digital pin to be continuously in the high level state all the time, the controller 55 may select the first electrode 52 to output a high level through the ADC analog-to-digital pin, the controller 55 detects a target level signal of the second electrode 53, and repeatedly determines the liquid level state of the water tank 51 according to the target level signal.

For another example, when the liquid level state is detected, the controller 55 sets the I/O pin to be in the low level state and sets the ADC analog-to-digital pin to be in the high level state, or the controller 55 sets the I/O pin to be switched from the high resistance state to the low level state and sets the ADC analog-to-digital pin to be continuously in the high level state all the time, since the liquid is not enough to turn on the first electrode 52 and the second electrode 53 for the first time, the sampling voltage is 0, and thus the controller 55 preliminarily determines that the liquid level state is in the anhydrous state or the underfill state.

Considering that the sampling voltage is 0 due to the abnormality of the line or the electrode, the controller 55 sets the I/O pin to be in a high level state and sets the ADC analog-to-digital pin to be in a low level state, or the controller 55 sets the I/O pin to be continuously in the high level state and sets the ADC analog-to-digital pin to be switched from the high resistance state to the low level state, the controller 55 may select the second electrode 53 to output the high level through the I/O pin, the controller 55 detects the target level signal of the first electrode 52, and repeatedly determines the liquid level state of the water tank 51 according to the target level signal.

In some embodiments, when the controller 55 repeatedly determines the liquid level state of the water tank 51 according to the target level signal, first, the controller 55 determines whether the target level signal is greater than or equal to a preset level threshold, if so, determines the liquid level state of the water tank 51 as the no-water state again when the liquid level state is the no-water state, and determines the liquid level state of the water tank 51 as the no-full state again when the liquid level state is the no-full state. If not, it is determined that the water tank assembly 500 is in an abnormal state.

With continued reference to fig. 10, in some embodiments, the line detection circuit 58 includes a diode, an anode of which is electrically connected to the first electrode 52 and a cathode of which is electrically connected to the second electrode 53. Due to the unidirectional conductivity of the diode, it does not affect normal no/full water detection. After the initial detection of the no-water state or the low-level state, the controller 55 selects the first electrode element 52 to output the high level, and when the loop 59 is disconnected at a certain position (for example, a cold solder occurs between the circuit and the first electrode pad 52 or the second electrode pad 53, or the circuit itself is broken by pressure), so that the controller 55 detects the no-water state or the low-level state, the diode cannot conduct, and thus, the target level signal detected by the controller 55 through the second electrode element 53 is close to or equal to 0. When the respective electrode pads and lines in the circuit 59 are normal, the controller 55 detects a no-water state or a low-full state because there is not a sufficient amount of water, but since the circuit is normal, the target level signal detected by the second pole element 53 is relatively large, and thus the controller 55 can repeatedly confirm the liquid level state of the water tank 51 again based on the target level signal.

In some embodiments, the difference from the above embodiments is that the line detection circuit 58 includes a line resistor with a relatively large resistance value, and the line resistor has a relatively large resistance value, so that the determination of the water presence state or the satisfied state is relatively unaffected. After the initial detection of the no water condition or the underfill condition, the controller 55 selects the first pole element 52 to output a high level, and if the target level signal detected by the second pole element 53 is a high level, the circuit 59 is normal. The loop 59 is abnormal if the target level signal detected by the second pole element 53 is low.

In some embodiments, the difference from the above embodiments is that the line detection circuit 58 includes a capacitor, and the determination of the water presence state or the satisfied state is not affected due to the blocking characteristic of the capacitor. After the initial detection of the no-water condition or the underfill condition, the controller 55 selects the first pole element 52 to output the PWM pulse wave, which can be transmitted to the second pole element 53 through the capacitor, so that the controller 55 detects that the circuit 59 is normal if the target level signal detected by the second pole element 53 is high. The loop 59 is abnormal if the target level signal detected by the second pole element 53 is low.

It is understood that the manner of line detection is various and is not limited to that provided herein and will not be described herein.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; within the idea of the invention, also technical features in the above embodiments or in different embodiments can be combined, steps can be implemented in any order, and there are many other variations of the different aspects of the invention as described above, which are not provided in detail for the sake of brevity; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A water tank assembly, comprising:

a water tank including a receiving chamber for storing liquid;

the first electrode piece is arranged in the accommodating cavity;

the second electrode piece is arranged in the accommodating cavity, and a vertical height difference is formed between the second electrode piece and the first electrode piece;

the sampling circuit is electrically connected with the first electrode element;

the controller, respectively with first electrode spare the second electrode spare reaches the sampling circuit electricity is connected, is used for selecting first electrode spare with one of them electrode spare output level signal in the second electrode spare, so that first electrode spare, save in the liquid of water tank the second electrode spare reaches the sampling circuit can form the detection return circuit.

2. The water tank assembly of claim 1 wherein an initial on position of said first pole element and said second pole element in said detection circuit is at a bottom of said water tank.

3. The water tank assembly as recited in claim 2, wherein said first pole member is disposed at a bottom of said water tank, said second pole member is disposed at a top of said water tank and one end thereof is bent to extend toward a bottom of said water tank.

4. The water tank assembly of claim 3, wherein said second pole member comprises:

one end of the first straight line part penetrates through the water tank and extends into the accommodating cavity, and the other end of the first straight line part is positioned outside the accommodating cavity;

one end of the first bending part is connected with one end of the first straight line part, and the other end of the first bending part extends towards the bottom of the water tank in a bending mode.

5. The water tank assembly of claim 1 wherein an initial on position of said first pole element and said second pole element in said detection circuit is at a top of said water tank.

6. The water tank assembly as recited in claim 5, wherein said first pole member is disposed at a bottom of said water tank and one end thereof is bent to extend toward a top of said water tank, and said second pole member is disposed at a top of said water tank.

7. The water tank assembly as claimed in any one of claims 1 to 6, further comprising a partition vertically installed in the receiving cavity to divide the receiving cavity into a liquid chamber and an isolation chamber, wherein one end of the first electrode and one end of the second electrode both extend to the liquid chamber after passing through the partition.

8. The water tank assembly of claim 7 further comprising a line detection circuit disposed within said isolation chamber, said line detection circuit being electrically connected between said first pole element and said second pole element.

9. The water tank assembly of claim 8 wherein said line detection circuit comprises a diode having an anode electrically connected to said first pole member and a cathode electrically connected to said second pole member.

10. A robot comprising a water tank assembly as claimed in any one of claims 1 to 9.

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