CN218018548U - Robot capable of carrying disinfection water tank - Google Patents

Abstract

The utility model discloses a robot capable of carrying a disinfection water tank, which comprises a chassis and a bracket, wherein an accommodating cavity which is provided with an upward opening and is used for connecting an electronic component is arranged in the chassis; the bracket is detachably connected above the chassis; the bracket is sunken downwards from the upper end surface to form an accommodating space, a circle of flange extends upwards from the bottom wall of the accommodating space, and the circle of flange surrounds the accommodating space for placing the lower side of the disinfection water tank; the flange is at least provided with a gap, correspondingly, a drain hole penetrates through the side wall of the accommodating space, and a drain channel is concavely arranged on the bottom wall of the accommodating space between the gap and the drain hole; the lower side of the outer side wall of the side, at least provided with the drain hole, of the bracket accommodating space is positioned on the outer side of the upper side of the outer side wall of the corresponding position of the chassis. By such arrangement, the disinfectant in the accommodating space can be discharged out of the bracket through the notch, the drainage channel and the drainage hole, and can not enter the accommodating cavity to damage the electronic components in the accommodating cavity.

Description

Robot capable of carrying disinfection water tank

Technical Field

The utility model relates to a robot product field especially relates to a can carry on robot of disinfection water tank.

Background

At present, epidemic situation spreads globally, disinfection and sterilization of public environment becomes a normal state, if manual operation wastes time and labor, a robot is adopted to execute the work, time and labor are saved, and non-contact operation is realized, so that the operation is relatively safe and reliable.

At present, the common mode of disinfection by a robot is to directly carry a system module carrying a spray disinfection water tank on a chassis of the robot. As shown in fig. 1 and 2, the robot chassis 100 has a receiving cavity 101 for electronic components to connect therein, the upper end of the robot chassis 100 is directly recessed to form a receiving space 102, a circle of protruding ribs 103 is protruded upward on the bottom wall of the receiving space 102 to form a receiving space 104, and the lower end of the spray disinfection water tank is disposed in the receiving space 104 and is positioned. Considering the later maintenance work of the robot chassis, a maintenance hole communicated with the accommodating cavity 101 is formed in the bottom wall of the accommodating space 104, a flat maintenance cover plate 105 is detachably connected with the bottom wall of the accommodating space, the maintenance cover plate 105 is connected to the bottom wall of the accommodating space at ordinary times to block the maintenance hole, the upper end surface of the maintenance cover plate is level with other bottom walls of the accommodating space, and most of the weight of the disinfection water tank is borne by the maintenance cover plate; during maintenance, the disinfection water tank needs to be removed first, and then the maintenance cover plate 105 needs to be detached, so that the electronic components in the accommodating cavity 101 can be maintained.

The current design of the robot has the following defects:

1. the connecting position of the maintenance cover plate and the chassis is in the accommodating space accommodated at the lower side of the disinfection water tank, so that if disinfection water flows into the accommodating space (due to the fact that a robot is adopted to carry the disinfection water tank, many unexpected complex environments and unexpected situations exist from transportation to use, and the accidental flow of the disinfection water into the accommodating space is something which cannot be avoided), the disinfection water can easily seep into the accommodating cavity from the seam between the maintenance cover plate and the maintenance hole to damage electronic components; however, the related components of the robot carrying the disinfection water tank are all produced by adopting a rapid die mode at present, so that the manufacturing precision of the related components of the robot is difficult to guarantee, the waterproof reliability of the robot is difficult to guarantee for the waterproof design scheme completely depending on the waterproof ring, and the disinfection water is still likely to seep into the accommodating cavity to damage the electronic components, so that the service life of the electronic components is shortened, the use cost of the robot is improved, and frequent maintenance is required (whether the disinfection water seeps into the accommodating cavity is frequently checked, if so, the damaged electronic components are required to be replaced, and the drying operation is required to be carried out on the accommodating cavity), so that the labor cost and the time cost of maintenance are also increased; if one robot needs to be maintained frequently, the time for carrying the disinfection water tank to disinfect is short, so that the disinfection efficiency is reduced;

2. the dimension of the maintenance hole and the maintenance cover plate under the traditional design is limited, so that the maintenance space is small, and the maintenance personnel can not maintain the electronic component in the chassis accommodating cavity through the maintenance hole;

3. although the diapire of chassis accommodation space has born the weight of partial disinfection water tank, the weight majority of disinfection water tank all is that the maintenance apron is undertaking, and the flat poor intensity of maintenance apron, and the weight of bearing is limited to once can not the carried sterile water can not be too much, so, need refill the frequency of sterile water just high relatively, thereby reduced disinfection's efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned shortcoming, provide a can carry on disinfection water tank's robot.

In order to achieve the above object, the utility model adopts the following technical scheme:

a robot capable of carrying a disinfection water tank comprises electronic components, the robot comprises a chassis and a bracket, and an accommodating cavity which is provided with an upward opening and is used for connecting the electronic components is arranged in the chassis; the bracket is detachably connected above the chassis; the bracket is sunken downwards from the upper end surface to form an accommodating space, a circle of flange extends upwards from the bottom wall of the accommodating space, and the circle of flange surrounds the accommodating space for placing the lower side of the disinfection water tank; the flange is at least provided with a notch, correspondingly, a drain hole penetrates through the side wall of the accommodating space on the side corresponding to the notch, and a drain channel is concavely arranged on the bottom wall of the accommodating space between the notch and the drain hole; the lower side of the outer side wall of the side, at least provided with the drain hole, of the bracket accommodating space is positioned on the outer side of the upper side of the outer side wall of the corresponding position of the chassis.

The accommodation space upwards extends from the diapire and has a plurality of first strengthening ribs, just the height that highly is less than the flange of first strengthening rib.

The first reinforcing ribs are formed into a grid shape.

The back of the bottom wall of the accommodating space of the bracket is provided with a plurality of second reinforcing ribs.

A cavity which is opened downwards is arranged on the side wall of the bracket accommodating space corresponding to the side wall of the chassis, so that the side wall of the bracket accommodating space is divided into a first side wall and a second side wall by the cavity, the first side wall is positioned on the outer side of the second side wall, and the first side wall is connected with the upper end of the second side wall; the lower side of the first side wall is positioned on the outer side of the upper side of the outer side wall at the corresponding position of the chassis.

The first side wall extends downwards and outwards in an inclined manner; or the first side wall comprises a first section extending downwards and outwards in an inclined manner and a second section extending downwards from the first section, and an included angle between the second section and the first section is less than 180 degrees; at least the lower side of the second section surrounds the outer side of the upper side of the outer side wall at the corresponding position of the chassis.

The bracket is provided with a connecting part between the first side wall and the second side wall at the corresponding position of the first through hole and the second through hole, the connecting part is provided with a through hole for communicating the first through hole and the second through hole, and the first through hole, the through hole and the second through hole at the corresponding positions form the drain hole.

The upper end of the side wall of the chassis is arranged to be the upper end of the side wall of the containing cavity, the upper end of the side wall of the corresponding position of the containing cavity is positioned in the cavity, and the second side wall is positioned on the inner side of the side wall of the corresponding position of the containing cavity.

The chassis is provided with an inner flange extending from the inner wall of the upper side wall, and the lower end of the second side wall is abutted against the inner flange.

A metal support plate with a through hole penetrating up and down is arranged in the middle of the flange, and the lower end of the second side wall is abutted to the metal support plate.

The utility model discloses can carry on disinfection water tank's robot is because adopted above-mentioned technical scheme to it does to have following beneficial effect:

1. even if the containing space is filled with disinfectant, the disinfectant can flow into the drainage channel from the gap and finally pass through

The drain hole is arranged outside the bracket; the lower side of the outer side wall of one side of the bracket accommodating space, which is provided with the drain hole, is positioned at the outer side of the upper side of the outer side wall of the corresponding side of the chassis, so that the disinfectant discharged through the drain hole cannot enter the accommodating cavity, and thus, the disinfectant is prevented from seeping into the accommodating cavity to damage electronic components in the accommodating cavity, the service life of the electronic components is greatly prolonged, the use cost of the robot is reduced, and the robot is not required to be frequently maintained due to worrying about the seepage of the disinfectant, so that the labor cost and the time cost of maintenance are greatly reduced; the maintenance frequency and time of the robot are reduced, and the time for carrying the disinfection water tank to disinfect and sterilize the robot is relatively increased, so that the disinfection and sterilization efficiency of the robot is improved;

2. the bracket with the design has the strength far higher than that of a flat maintenance cover plate in the prior art,

the disinfection water tank is arranged on the bracket, so that the bracket can bear heavier disinfection water at one time, namely the disinfection water tank arranged on the bracket can contain more disinfection water at one time, so that the frequency of filling the disinfection water is reduced, and the disinfection and sterilization efficiency of the robot is further improved;

3. by adopting the bracket and the connection mode of the bracket and the chassis, the bracket becomes a big piece,

after the bracket is detached from the chassis, more space can be exposed out of the whole chassis, so that the upward opening of the chassis accommodating cavity can be set to be larger, namely the maintenance hole can be made larger, and maintenance personnel can conveniently maintain the electronic components in the chassis accommodating cavity through the opening;

4. because the design is adopted, the disinfectant can be prevented from seeping into the containing cavity, thereby the utility model is made

The novel robot does not need to be provided with a waterproof ring, so that the precision requirement of the chassis and bracket manufacturing process is lowered.

Drawings

FIG. 1 is a schematic view of a conventional robot carrying a disinfectant tank;

FIG. 2 is an exploded view of a conventional robot carrying a sterilizing water tank;

FIG. 3 is a schematic plan view of a robot capable of carrying a disinfection water tank according to the present invention;

FIG. 4 is a perspective view of the robot with the disinfection water tank;

FIG. 5 is an exploded view of a robot capable of carrying a sterilizing water tank according to the present invention;

FIG. 6 is a schematic view of a robot chassis capable of carrying a disinfection water tank;

FIG. 7 is a schematic view of a bracket of a robot capable of carrying a disinfection water tank according to the present invention;

FIG. 8 is an enlarged view of the portion B of FIG. 6;

FIG. 9 is another schematic view of the bracket of the robot capable of carrying the sterilizing water tank according to the present invention;

FIG. 10 is an enlarged view taken along the line A-A in FIG. 4;

FIG. 11 is an enlarged view of the portion C of FIG. 10;

fig. 12 is an exploded view of the chassis of the robot with the sterilizing water tank according to the present invention.

Detailed Description

As shown in fig. 3 to 11, the utility model relates to a robot capable of carrying a disinfection water tank, which comprises an electronic component 1, wherein the robot comprises a chassis 2 and a bracket 3, and an accommodating cavity 21 which is opened upwards and is used for connecting the electronic component 1 is arranged in the chassis 2; the bracket 3 is detachably connected above the chassis 2; the bracket 3 is recessed downwards from the upper end face to form an accommodating space 31, a circle of flanges 32 extend upwards from the bottom wall of the accommodating space 31, and the circle of flanges 32 enclose an accommodating space 33 for accommodating the lower side of the disinfection water tank; the flange 32 is at least provided with a notch 321, correspondingly, a drain hole 34 is formed through the sidewall of the accommodating space 31 on the side corresponding to the notch 321, and a drain channel 35 is concavely formed on the bottom wall of the accommodating space 31 between the notch 321 and the drain hole 34; the lower side of the outer side wall of the bracket accommodating space 31 at least provided with the drain hole 34 is positioned outside the upper side of the outer side wall of the corresponding position of the chassis 2. That is, if the drain hole 34 is formed in the sidewall of one side of the tray accommodating space 31, at least the lower side of the outer sidewall of the one side of the tray accommodating space 31 is located outside the upper side of the outer sidewall of the one side of the chassis 2; if the drain hole 34 is not provided on the other side of the bracket accommodating space 31, the lower side of the outer wall of the other side accommodating space 31 may be located outside the upper side of the outer wall of the chassis 2.

The structure and function of the electronic component 1 are common knowledge and will not be described herein.

When in use, the lower side of the disinfection water tank is arranged in the accommodating space 33 of the bracket 3, so that the disinfection water tank can not move and is positioned; when the electronic component 1 in the accommodating cavity 21 needs to be maintained, the sterilizing water tank is firstly removed, and then the bracket 3 is detached from the chassis 2. In this way, the bracket 3 integrates the function of a carrier of the disinfectant tank with the maintenance cover of the chassis 2.

Because the robot capable of carrying the disinfection water tank of the utility model adopts the arrangement, even if the disinfection water exists in the accommodating space 33, the disinfection water flows into the drainage channel 35 from the notch 321 and is finally drained out of the bracket 3 through the drainage hole 34; and because the lower side of the outer side wall of the side of the tray accommodating space 31 where the drain hole 34 is provided is located at the outer side of the upper side of the outer side wall of the corresponding side of the chassis 2, the sterilizing water discharged through the drain hole 34 cannot enter the accommodating cavity 21 to damage the electronic component 1. That is, because the robot of the present invention adopts the above arrangement, it is possible to prevent the sterilizing water from penetrating into the accommodating chamber 21. So, avoided the disinfectant to ooze into in the holding chamber 21 and harm electronic components 1 in the holding chamber 21 to not only prolonged electronic components 1's life greatly, reduced the use cost of robot, also need not to carry out frequent maintenance to the robot because of worrying that the disinfectant oozes in addition, thereby greatly reduced the cost of labor and the time cost of maintaining. The maintenance frequency and time of the robot are reduced, and the time for carrying the disinfection water tank to disinfect and sterilize the robot is relatively increased, so that the disinfection and sterilization efficiency of the robot is improved; in addition, the strength of the bracket 3 with the design is far greater than that of a flat maintenance cover plate in the traditional technology, and the disinfection water tank is carried on the bracket 3, so that the bracket 3 can bear heavier disinfection water at one time, namely, the disinfection water tank carried on the bracket 3 can contain more disinfection water at one time, so that the frequency of filling disinfection water is reduced, and the disinfection and sterilization efficiency of the robot is further improved; moreover, the bracket 3 and the connection mode of the bracket 3 and the chassis 2 are adopted, so that the bracket 3 becomes a large piece, and after the bracket 3 is detached from the chassis 2, more space can be exposed out of the whole chassis 2, that is, an upward opening of the chassis accommodating cavity 21 can be set to be larger, that is, a maintenance hole can be made larger, so that a maintainer can conveniently maintain the electronic component 1 in the chassis accommodating cavity 21 through the opening; and because adopted above-mentioned design, make the utility model discloses the robot need not to set up waterproof circle to the required precision of the manufacturing process of chassis 2 and bracket 3 has been reduced.

In this embodiment, the flange 32 is provided with notches 321 on two different sides, correspondingly, the accommodating space 31 is provided with drain holes 34 respectively corresponding to the side walls on the two sides, two rows of water channels 35 are concavely provided on the bottom wall of the accommodating space 31, and each drain channel 35 is connected to one notch 321 and one drain hole 34. Thus, two drainage systems (each comprising a notch 321, a drainage channel 35 and a drainage hole 34) are provided at different positions, so that the sterilized water overflowing from the accommodating space 33 can be discharged through the drainage systems more quickly.

Preferably, the accommodating space 33 extends upward from the bottom wall to form a plurality of first ribs 36, and the height of the first ribs 36 is lower than the height of the flange 32. When the lower side of the disinfection water tank is arranged in the accommodating space 33, namely, the lower end of the disinfection water tank is arranged on the first reinforcing rib 36. Because the height of the first reinforcing rib 36 is lower than that of the flange 32, the distance between the top end of the flange 32 and the top end of the first reinforcing rib 36 does not affect the positioning of the accommodating space 33 on the sterilizing water tank. The setting of first strengthening rib 36 can increase the intensity of bracket 3 to make the utility model discloses the bracket 3 intensity of robot is more than flat maintenance apron in the conventional art far away, makes the utility model discloses the robot once only carries on more sterile water.

In the present embodiment, the plurality of first reinforcing ribs 36 are formed in a grid shape. With this arrangement, when a small amount of sterilizing water flows into the accommodating space 33, the sterilizing water is temporarily stored in the grating 361 formed by the first reinforcing ribs 36, and only when the amount of the sterilizing water is large enough to overflow the grating, the sterilizing water is discharged through the drainage system. With such an arrangement, it is also possible to prevent the sterile water from being discharged through the drainage system when the sterile water flows into the accommodating space 33, and to pour out the sterile water in the grille after reaching the recycling site.

Preferably, the bracket 3 is also provided with a plurality of second reinforcing ribs 37 (as shown in fig. 8) on the back side (i.e. the side facing the chassis 2) of the bottom wall of the accommodating space 31, so as to further increase the strength of the bracket 3.

As shown in fig. 7, 9, 10 and 11, in the present embodiment, the side wall of the tray accommodating space 31 corresponding to the side wall of the chassis 2 is provided with a cavity 30 opened downward, so that the cavity 30 divides the side wall of the tray accommodating space 31 into a first side wall 38 and a second side wall 39, the first side wall 38 is located outside the second side wall 39, and the first side wall 38 is connected to the upper end of the second side wall 39; the lower side of the first side wall 38 is located outside the upper side of the outer side wall at the corresponding position of the chassis 2. Due to the arrangement, compared with the solid side wall, the bracket 3 has light weight as a whole, and the raw materials for manufacturing the bracket 3 are less, so that the cost for manufacturing the bracket 3 is reduced; and by such arrangement, the function of the bracket 3 for preventing the sterilization water from penetrating into the accommodating cavity 21 is not influenced.

Preferably, the first sidewall 38 includes a first section 381 extending downward and outward in an oblique manner, and a second section 382 extending downward from the first section 381, and an included angle between the second section 382 and the first section 381 is less than 180 degrees; at least the lower side of the second section 382 surrounds the outer side of the upper side of the outer side wall at the corresponding position of the chassis 2, namely, the lower side of the outer side wall of the bracket 3 and the upper side of the outer side wall of the chassis 2 form an upper-lower structure. With such an arrangement, the disinfectant coming out from the water discharge hole 34 flows downwards along the outer wall of the inclined first section 381, and when the disinfectant flows to the lowest end of the first section 381, the disinfectant basically directly falls to the ground due to gravity, rather than continuously flowing along the outer wall of the second section 382, so as to prevent the disinfectant from entering the accommodating cavity 21 of the chassis 2.

In other embodiments, the first sidewall 38 may extend downward and outward in an inclined manner to form an eave. Thus, the sterilizing water discharged from the water discharge hole 34 does not enter the housing chamber 21 of the chassis 2.

Preferably, a plurality of third ribs 301 are spaced apart from each other in the cavity 30, and both ends of each of the third ribs are connected to the first side wall 38 and the second side wall 39, respectively. In this way, the strength of the bracket 3 can be enhanced while keeping the bracket 3 relatively lightweight.

The corresponding positions of the first sidewall 38 and the second sidewall 39 are respectively provided with a first through hole 381 (as shown in fig. 7) and a second through hole 392 (as shown in fig. 8) which are penetrated through, and the bracket 3 is provided with a connecting portion 302 which connects the first sidewall 38 and the second sidewall 39 between the first sidewall 38 and the second sidewall 39 at the corresponding positions of the first through hole 381 and the second through hole 391, the connecting portion 302 is provided with a through hole (not shown) which connects the first through hole 381 and the second through hole 392, and the first through hole, the through hole and the second through hole at the corresponding positions are formed as the drainage hole 34.

In the present embodiment, the upper side of the side wall of the chassis 2 is set as the side wall upper side 210 (as shown in fig. 5) of the accommodating cavity 21, that is, the upper end of the side wall of the chassis 2 is the side wall upper end of the accommodating cavity 21; the upper end of the side wall corresponding to the accommodating cavity 21 is located in the cavity 30, and the second side wall 39 is located inside the side wall corresponding to the accommodating cavity 21 (as shown in fig. 10 and 11). The third reinforcing rib 301 is located above the side wall of the corresponding position of the accommodating cavity 21, so that interference cannot be generated to influence the connection between the bracket 3 and the chassis 2.

The upper connecting portion 310 is disposed between the first side wall 38 and the second side wall 39.

Referring to fig. 6, 9 and 12, a plurality of lower connecting portions 23-1 and 23-2 are provided at intervals on the inner side of the upper side of the side wall of the chassis accommodating cavity 21, and correspondingly, a plurality of upper connecting portions 310-1 and 310-2 are provided at intervals on the lower side of the side wall of the accommodating space 31, and the upper connecting portions are detachably connected with the corresponding lower connecting portions, so that the bracket 3 is detachably connected with the chassis 2. The upper connecting part can be provided with a screw hole with a downward opening, correspondingly, the lower connecting part is provided with a counter bore or a through hole (as shown in fig. 6), and a screw penetrates through the counter bore/the through hole upwards and then is locked into the screw hole. When the lower connecting part 23-2 is a countersunk hole or a through hole, a gap for screwing screws is formed between the position of the chassis 2 where the lower connecting part 23 is arranged and other components of the chassis 2. The gap is set to be a known technology, and is not a key point of the present invention, and therefore, is not described herein. Or the lower connecting part is provided with a screw hole with an upward opening, the upper connecting part is provided with a counter bore or a through hole, and the screw penetrates through the counter bore/the through hole upwards and then is locked into the screw hole. In the present embodiment, of the lower connection portions, a portion (as shown in fig. 23-1) is provided with a screw hole, and another portion is provided with a counter bore or a through hole 23-2; correspondingly, a part (shown as 310-1 in the figure) of the connecting parts is provided with a screw hole, and the other part is provided with a counter bore or a through hole 310-2. This makes the connection of the connected bracket 3 to the chassis more stable.

Referring to fig. 7 and 9, in this embodiment, the upper connecting portion 310-2 configured as a countersunk hole or a through hole is disposed on the connecting portion 302, the sidewall of the accommodating space 31 is provided with an avoiding groove 300 corresponding to the position of the connecting portion 302, and the upper connecting portion 310-2 is provided on the bottom wall of the avoiding groove 300, so that a screw can be locked into the screw hole of the lower connecting portion 23-1 from the top to the bottom of the avoiding groove 300. A stopper 5 is fixedly coupled to the avoiding groove 300, and the stopper 5 and the avoiding groove together form the drain passage 35. The through hole connecting the first through hole 381 and the second through hole 392 is disposed at an interval from the upper connecting portion 310-2 disposed on the connecting portion 302.

In other embodiments, the bracket 3 may be provided with other connecting portions at other positions between the first side wall 38 and the second side wall 39 for providing the connecting portion of the upper connecting portion 310-2, and correspondingly, the position of the lower connecting portion 23-1 is changed correspondingly. That is, the bracket 3 is provided with a connecting portion 302 for connecting the through holes of the first through hole 381 and the second through hole 392 and another connecting portion for providing the upper connecting portion 310-2 between the first side wall 38 and the second side wall 39, and similarly, the side wall of the accommodating space 31 is provided with an avoiding groove at a position corresponding to the connecting portion, the upper connecting portion is provided with a bottom wall of the avoiding groove, and a stopper is fixedly connected to the avoiding groove.

In other embodiments, the bracket 3 and the chassis 2 can be detachably connected by other known and feasible structures.

As shown in fig. 6, 9 to 12, in the present embodiment, the bottom plate 2 is provided with an inner flange 22 extending from an inner wall of the upper side wall, and a lower end of the second side wall 39 abuts against the inner flange 22. So arranged, the bracket 3 can be supported by the chassis 2 more strongly, thereby leading the sterilizing water tank to be carried more stably. Preferably, a metal support plate 4 with a through hole 41 penetrating up and down in the middle is placed on the flange 32, and the lower end of the second side wall 39 abuts against the metal support plate 4 (as shown in fig. 11). The arrangement of said metal support plate 4 makes it possible for the chassis 1 to withstand greater forces, so that the carriage 2, whose lower end portion is in abutment with the metal support plate, is more stably and powerfully supported and can withstand greater pressures, that is to say, so that the carriage 2 can carry more sterile water at a time.

In the present embodiment, preferably, the lower end of the portion 37-1 of the plurality of second reinforcing ribs 37 close to the second side wall 39 also abuts against the metal supporting plate 4. That is, of the plurality of second reinforcing beads 37, the second reinforcing bead partially adjacent to the second side wall 39 has a second lower end flush with the lower end of the second side wall 39 so as to abut against the metal support plate 4 together with the lower end of the second side wall 39. In this way, the contact area of the bracket 2 with the metal support plate 4 of the chassis 1 is increased, so that the bracket 2 can bear more pressure and can bear more disinfectant water at one time. The lower end surfaces of the other portions of the plurality of second reinforcing beads 37 may be located at a level above the level of the upper end surface of the metal support plate 4.

Since the metal supporting plate 4 is only used for the second reinforcing rib at the lower end of the second side wall 39 and near the second side wall 39, the through hole 41 in the middle of the metal supporting plate 4 can be made as large as possible, so that the maintenance work entering the accommodating cavity 21 is not limited.

Preferably, the metal supporting plate 4 is a steel plate, so that the strength can be ensured and the weight is not too heavy. The above disclosure is only for the preferred embodiment of the present invention, and the scope of the right of the present invention cannot be limited thereby, and therefore, the equivalent changes made according to the present invention still belong to the scope covered by the present invention.

Claims (10)

1. The utility model provides a can carry on robot of disinfection water tank, its includes electronic components, its characterized in that: the robot comprises a chassis and a bracket, wherein an accommodating cavity which is opened upwards and is used for connecting the electronic component is arranged in the chassis; the bracket is detachably connected above the chassis; the bracket is sunken downwards from the upper end surface to form an accommodating space, a circle of flange extends upwards from the bottom wall of the accommodating space, and the circle of flange surrounds an accommodating space for placing the lower side of the disinfection water tank; the flange is at least provided with a notch, correspondingly, a drain hole penetrates through the side wall of the accommodating space on the side corresponding to the notch, and a drain channel is concavely arranged on the bottom wall of the accommodating space between the notch and the drain hole; the lower side of the outer side wall of the side, at least provided with the drain hole, of the bracket accommodating space is positioned on the outer side of the upper side of the outer side wall of the corresponding position of the chassis.

2. The robot carrying the sterilizing water tank as set forth in claim 1, wherein: the accommodation space upwards extends from the diapire and has a plurality of first strengthening ribs, just the height that highly is less than the flange of first strengthening rib.

3. The robot carrying the sterilizing water tank as set forth in claim 2, wherein: the first reinforcing ribs are formed into a grid shape.

4. A robot carrying a sterilizing water tank according to claim 1, 2 or 3, wherein: the back of the bottom wall of the accommodating space of the bracket is provided with a plurality of second reinforcing ribs.

5. A robot carrying a sterilizing water tank according to any one of claims 1 to 4, characterized in that: a cavity with a downward opening is arranged on the side wall of the bracket accommodating space corresponding to the side wall of the chassis, so that the side wall of the bracket accommodating space is divided into a first side wall and a second side wall by the cavity, the first side wall is positioned on the outer side of the second side wall, and the upper ends of the first side wall and the second side wall are connected; the lower side of the first side wall is positioned at the outer side of the upper side of the outer side wall at the corresponding position of the chassis; preferably, a plurality of third reinforcing ribs are arranged in the cavity at intervals, and two ends of each reinforcing rib are respectively connected with the first side wall and the second side wall.

6. The robot capable of carrying a sterilizing water tank according to claim 5, wherein: the first side wall extends downwards and outwards in an inclined manner; or the first side wall comprises a first section extending downwards and outwards in an inclined manner and a second section extending downwards from the first section, and an included angle between the second section and the first section is less than 180 degrees; at least the lower side of the second section surrounds the outer side of the upper side of the outer side wall at the corresponding position of the chassis.

7. A robot carrying a sterilizing water tank according to claim 5 or 6, characterized in that: the bracket is provided with a connecting part between the first side wall and the second side wall at the corresponding position of the first through hole and the second through hole, the connecting part is provided with a through hole for communicating the first through hole and the second through hole, and the first through hole, the through hole and the second through hole at the corresponding positions form the drain hole.

8. A robot carrying a sterilizing water tank according to claim 5, 6 or 7, characterized in that: the upper end of the side wall of the chassis is arranged to be the upper end of the side wall of the containing cavity, the upper end of the side wall of the corresponding position of the containing cavity is positioned in the cavity, and the second side wall is positioned on the inner side of the side wall of the corresponding position of the containing cavity.

9. The robot carrying the sterilizing water tank as set forth in claim 8, wherein: the chassis is provided with an inner flange extending from the inner wall of the upper side wall, and the lower end of the second side wall is abutted against the inner flange.

10. A robot carrying a sterilizing water tank according to claim 9, wherein: a metal support plate with a through hole penetrating up and down is arranged in the middle of the flange, and the lower end of the second side wall is abutted to the metal support plate.

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