CN218595161U

CN218595161U - Deodorization mechanism of garbage can and garbage can

Info

Publication number: CN218595161U
Application number: CN202122116852.5U
Authority: CN
Inventors: 徐健
Original assignee: Shanghai Townew Intelligent Technology Co Ltd
Current assignee: Shanghai Townew Intelligent Technology Co Ltd
Priority date: 2020-11-30
Filing date: 2021-09-02
Publication date: 2023-03-10
Anticipated expiration: 2031-09-02
Also published as: CN114572582A; CN218595159U; CN216302223U; CN218595160U; CN218595162U; CN218143571U; CN218113818U; CN114572582B

Abstract

The embodiment of the utility model relates to an intelligence furniture, in particular to deodorant mechanism and garbage bin of garbage bin, deodorant mechanism includes: the first movable rod, the second movable rod, the third movable rod and the fixed rod; the first movable rod and the second movable rod are arranged oppositely and parallelly along a first preset linear direction; the third movable rod and the fixed rod are arranged oppositely and parallelly along a second preset linear direction; the driving device is respectively connected with the first movable rod, the second movable rod and the third movable rod and used for driving the first movable rod and the second movable rod to move relative to each other and driving the third movable rod to move relative to the fixed rod, so that the first movable rod, the second movable rod, the third movable rod and the fixed rod can enclose a clamping area for opening or tightening the opening of the garbage bag. Compared with the prior art, the peculiar smell in the garbage bag can be effectively prevented from overflowing, so that the use feeling of a user is improved.

Description

Deodorization mechanism of garbage can and garbage can

Technical Field

The embodiment of the utility model relates to an intelligence furniture, in particular to deodorant mechanism and garbage bin of garbage bin.

Background

The intelligent garbage can automatically open and close the garbage can cover as one kind, and can also complete the intelligent furniture equipment capable of automatically packing, thoroughly solves the hidden danger of sanitary pollution of the traditional garbage can to a user, can effectively stop various infectious diseases from being propagated through garbage and prevent the odor of the garbage in the can from overflowing, and is more and more widely applied to families.

The inventor finds that as the intelligent garbage can often appears in the using process, the garbage bag has larger storage allowance or space, but the garbage in the garbage bag begins to be decomposed, so that the garbage generates odor and peculiar smell, at the moment, although the barrel cover closes the barrel opening, the odor still overflows outwards from a gap part between the barrel cover and the barrel opening, particularly, the phenomena of wet garbage, kitchen garbage, toilet garbage, baby diaper and the like are particularly obvious, and the use feeling of a user is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses embodiment's aim at designs deodorant mechanism and garbage bin of garbage bin, can not put in rubbish at the user, tightens up the sack of current disposal bag to can prevent effectively that the peculiar smell in the disposal bag from spilling over, and then improve user's use impression.

In order to solve the technical problem, the utility model provides an embodiment provides a deodorant mechanism of garbage bin sets up in the opening side of the staving of garbage bin, deodorant mechanism includes:

a deodorization clip; deodorant clamp includes: the first movable rod and the second movable rod are arranged oppositely and parallelly along the first preset linear direction; deodorant clamp still includes: the third movable rod and the fixed rod are oppositely and parallelly arranged along the second preset linear direction; the first preset linear direction is perpendicular to the second preset linear direction;

the driving device is respectively connected with the first movable rod, the second movable rod and the third movable rod; the driving device is used for driving the first movable rod and the second movable rod to move relative to each other along the first preset linear direction; the driving device is also used for driving the third movable rod to move relative to the fixed rod; the first movable rod, the second movable rod, the third movable rod and the fixed rod enclose a clamping area for opening or tightening the opening of the garbage bag;

the main control module is in communication connection with the driving device and is used for receiving a barrel cover opening instruction or a barrel cover closing instruction; the main control module is used for sending a first driving signal to the driving device after receiving a barrel cover closing instruction; the main control module is used for sending a second driving signal to the driving device after receiving a barrel cover opening instruction;

the driving device is used for driving the first movable rod and the second movable rod to move towards a mutually approaching direction and simultaneously driving the third movable rod to move towards a direction approaching the fixed rod when receiving the first driving signal;

the driving device is further used for driving the first movable rod and the second movable rod to move towards directions away from each other and driving the third movable rod to move towards a direction away from the fixed rod when receiving the second driving signal.

Additionally, the utility model discloses an embodiment still provides a garbage bin, include:

a barrel body; the staving is along predetermineeing the axis direction, has: an open side;

the odor prevention mechanism as described above;

the barrel cover is used for opening or closing the opening side of the barrel body;

and the control module is in communication connection with the main control module and is used for sending a barrel cover opening instruction or a barrel cover closing instruction to the main control module.

Compared with the prior art, when the user need not put into rubbish to the staving in, can send bung closed instruction to host system by controlling the module, accessible host system can be according to bung closed instruction this moment, send first drive signal to drive arrangement, make drive arrangement can drive first movable rod and second movable rod, the orientation motion that is close to each other, and simultaneously, drive third movable rod, the orientation motion that is close to the dead lever, in order to realize tightening up the disposal bag sack, thereby can effectively prevent that the produced peculiar smell of rubbish in the disposal bag from overflowing from the internal of bag, make user's use impression can improve. On the contrary, when the user needs to throw in rubbish to the staving, can send the bung to main control module by control module and open the instruction, and main control module can open the instruction according to the bung this moment, sends second drive signal to drive arrangement, makes drive arrangement can drive first movable rod and second movable rod towards the direction motion of keeping away from each other, drives the direction motion of third movable rod towards keeping away from the dead lever simultaneously to the realization is to the opening of the sack of disposal bag, thereby has guaranteed again that can not cause the influence to user's throwing in rubbish.

The driving device includes:

the driving assembly is in communication connection with the main control module and is used for receiving the first driving signal or the second driving signal;

the transmission assembly is connected with the driving assembly; the transmission assembly is further connected with the first movable rod, the second movable rod and the third movable rod.

In addition, the driving assembly includes:

the motor is in communication connection with the main control module and is used for receiving the first driving signal or the second driving signal;

the speed reducer is connected with the output end of the motor; wherein, the transmission assembly is connected with an output shaft of the speed reducer.

Additionally, the transmission assembly includes:

the first main synchronizing wheel is coaxially connected with an output shaft of the speed reducer;

the first slave synchronizing wheel is arranged opposite to the first master synchronizing wheel along the first preset linear direction;

a first timing belt connecting the first master synchronizing wheel and the first slave synchronizing wheel; the first synchronization belt has: a first inner transmission layer disposed towards the clamping region, a first outer transmission layer disposed away from the clamping region;

the second main synchronizing wheel is coaxially connected with an output shaft of the speed reducer;

the second slave synchronizing wheel is arranged opposite to the second master synchronizing wheel along the second preset linear direction;

the second synchronous belt is connected with the second main synchronous wheel and the second slave synchronous wheel; the second timing belt has: a second inner transmission layer disposed toward the clamping region, a second outer transmission layer disposed away from the clamping region;

wherein the first movable bar is connected to the first outer drive layer of the first timing belt and the second movable bar is connected to the first inner drive layer of the first timing belt;

the third movable rod is connected with the second outer transmission layer or the second inner transmission layer of the second synchronous belt.

In addition, deodorant mechanism still includes:

the first detection module is in communication connection with the main control module; the first detection module is used for detecting whether the first movable rod or the second movable rod moves to a first preset position or not when the first movable rod and the second movable rod move towards the direction close to each other; the first detection module is further used for sending a first detection signal to the main control module when the first movable rod or the second movable rod is detected to move to a first preset position;

the second detection module is in communication connection with the main control module; the second detection module is used for detecting whether the first movable rod or the second movable rod moves to a second preset position when the first movable rod and the second movable rod move towards the direction away from each other; the second detection module is further configured to send a second detection signal to the main control module when detecting that the first movable rod or the second movable rod moves to a second preset position;

the main control module is used for closing the driving component when receiving the first detection signal or the second detection signal.

In addition, deodorant mechanism still includes:

the third detection module is in communication connection with the main control module; the third detection module is used for detecting whether the third movable rod moves to a third preset position or not when the third movable rod moves towards the direction close to the fixed rod; the third detection module is further used for sending a third detection signal to the main control module when detecting that the third movable rod moves to a third preset position;

the fourth detection module is in communication connection with the main control module; the fourth detection module is used for detecting whether the third movable rod moves to a fourth preset position or not when the third movable rod moves towards the direction far away from the fixed rod; the fourth detection module is further configured to send a fourth detection signal to the main control module when detecting that the third movable rod moves to a fourth preset position;

the main control module is used for closing the driving component when receiving the third detection signal or the fourth detection signal.

Alternatively, the driving device includes:

the first driving assembly and the second driving assembly are in communication connection with the main control module and used for receiving the first driving signal or the second driving signal;

the first transmission assembly is connected with the first driving assembly; wherein the first transmission assembly is further connected with the first movable rod and the second movable rod;

the second transmission assembly is connected with the second driving assembly; wherein, the second transmission assembly is also connected with the third movable rod.

In addition, the first driving assembly includes:

the first motor is in communication connection with the main control module and is used for receiving the first driving signal or the second driving signal;

the first speed reducer is connected with the output end of the first motor; the first transmission assembly is connected with a first output shaft of the first speed reducer;

the second drive assembly includes:

the second motor is in communication connection with the main control module and is used for receiving the first driving signal or the second driving signal;

the second speed reducer is connected with the output end of the second motor; the second transmission assembly is connected with a second output shaft of the second speed reducer.

Additionally, the first transmission assembly includes:

the first main synchronizing wheel is coaxially connected with a first output shaft of the first speed reducer;

a first timing belt connecting the first master synchronizing wheel and the first slave synchronizing wheel; the first synchronization belt has: a first inner transmission layer disposed toward the clamping region, a first outer transmission layer disposed away from the clamping region;

the first movable rod is connected with the first outer transmission layer of the first synchronous belt, and the second movable rod is connected with the first inner transmission layer of the first synchronous belt.

Additionally, the second transmission assembly includes:

the second main synchronizing wheel is coaxially connected with a second output shaft of the second speed reducer;

the second slave synchronizing wheel is arranged opposite to the second master synchronizing wheel along the first preset linear direction;

the second synchronous belt is connected with the second main synchronous wheel and the second slave synchronous wheel; the second synchronous belt is specifically: a second inner transmission layer disposed toward the clamping region, a second outer transmission layer disposed away from the clamping region;

wherein the third movable rod is connected with the second outer transmission layer of the second synchronous belt or connected with the second inner transmission layer of the second synchronous belt.

In addition, deodorant mechanism still includes:

the first detection module is in communication connection with the main control module; the first detection module is used for detecting whether the first movable rod or the second movable rod moves to a first preset position or not when the first movable rod and the second movable rod move towards the direction of mutual approaching; the first detection module is further used for sending a first detection signal to the main control module when the first movable rod or the second movable rod is detected to move to a first preset position;

the second detection module is in communication connection with the main control module; the second detection module is used for detecting whether the first movable rod or the second movable rod moves to a second preset position when the first movable rod and the second movable rod move towards directions away from each other; the second detection module is further configured to send a second detection signal to the main control module when detecting that the first movable rod or the second movable rod moves to a second preset position;

the main control module is used for closing the first driving component when receiving the first detection signal or the second detection signal; the main control module is further configured to close the second driving component when receiving the third detection signal or the fourth detection signal.

In addition, the driving device further includes:

the first guide rod is arranged along the first preset linear direction and is in sliding connection with the first movable rod and the second movable rod;

and the second guide rod is arranged along the second preset linear direction and is in sliding connection with the third movable rod.

In addition, the two first guide rods are arranged, are opposite to each other along the second preset linear direction and are arranged in parallel; the two ends of the first movable rod are respectively connected with the two first guide rods in a sliding manner, and the two ends of the second movable rod are respectively connected with the two first guide rods in a sliding manner;

the two second guide rods are arranged oppositely along the first preset linear direction and are arranged in parallel; and two ends of the third movable rod are respectively connected with the two second guide rods in a sliding manner.

In addition, the first movable rod is connected with the third movable rod in a sliding manner along the first preset linear direction;

the second movable rods are connected with the third movable rods in a sliding mode along the first preset linear direction;

and the third movable rod is in sliding connection with the first movable rod and the second movable rod respectively along the second preset linear direction.

In addition, the first movable rod is provided with a first slide way along the second preset linear direction, and the second movable rod is provided with a second slide way along the second preset linear direction; the third movable rod is respectively arranged in the first slide way and the second slide way in a penetrating way;

or, a third slide way is arranged on the third movable rod along the first preset linear direction; wherein, first movable rod and second movable rod wear to locate respectively the third slide.

In addition, deodorant clamp still includes:

the first flexible layer is arranged on one side of the first movable rod opposite to the first movable rod or arranged on one side of the second movable rod opposite to the first movable rod;

and the second flexible layer is arranged on one side of the third movable rod relative to the fixed rod, or is arranged on one side of the fixed rod relative to the third movable rod.

In addition, deodorant clamp still includes:

the first buffer piece is arranged on one side of the first movable rod opposite to the second movable rod or one side of the second movable rod opposite to the first movable rod;

and the second buffer piece is arranged on one side of the third movable rod relative to the fixed rod, or arranged on one side of the fixed rod relative to the third movable rod.

In addition, the first preset linear direction is perpendicular to the second preset linear direction.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which are not to be construed as limiting the embodiments, in which elements having the same reference numeral designations represent like elements throughout, and in which the drawings are not to be construed as limiting in scale unless otherwise specified.

Fig. 1 is an assembly schematic view of the deodorization mechanism according to the first embodiment of the present invention when being combined with the tub;

fig. 2 is a schematic structural view of a deodorizing mechanism when a bag opening is opened by a deodorizing clamp according to a first embodiment of the present invention;

fig. 3 is a schematic structural view of the odor-resistant mechanism when the odor-resistant clip is at the mouth of the tightening bag in the first embodiment of the present invention;

fig. 4 is a schematic structural diagram of a driving device according to a first embodiment of the present invention;

fig. 5 is a system block diagram of a deodorization mechanism according to a first embodiment of the present invention;

fig. 6 is a schematic view illustrating the first movable bar being engaged with the first timing belt according to the first embodiment of the present invention;

fig. 7 is a schematic view illustrating the second movable bar being engaged with the first timing belt according to the first embodiment of the present invention;

fig. 8 is a schematic view illustrating the assembly of the deodorizing mechanism in the garbage can according to the first embodiment of the present invention;

fig. 9 is a schematic structural view of a first movable rod according to a first embodiment of the present invention;

fig. 10 is a schematic structural view of a deodorization mechanism according to a second embodiment of the present invention;

fig. 11 is a system block diagram of a deodorization mechanism according to a second embodiment of the present invention;

fig. 12 is a schematic structural view of another odor prevention mechanism according to a second embodiment of the present invention;

fig. 13 is a system block diagram of another odor prevention mechanism according to a second embodiment of the present invention;

fig. 14 is a schematic structural view of a deodorization mechanism according to a third embodiment of the present invention;

fig. 15 is a schematic structural view of a driving device according to a third embodiment of the present invention;

fig. 16 is a system block diagram of a deodorization mechanism according to a third embodiment of the present invention;

fig. 17 is a schematic structural view of a deodorization clip according to a third embodiment of the present invention;

fig. 18 is a schematic structural view of another anti-odor clamp according to a third embodiment of the present invention;

fig. 19 is a schematic structural view of a deodorization mechanism according to a fourth embodiment of the present invention;

fig. 20 is a system block diagram of a deodorization mechanism according to a fourth embodiment of the present invention;

fig. 21 is a schematic structural view of a trash can according to a fifth embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following describes each embodiment of the present invention in detail with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in various embodiments of the invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solution claimed in the present application can be implemented without these technical details and various changes and modifications based on the following embodiments.

Example one

The first embodiment of the present invention relates to a deodorization mechanism for a trash can, and as shown in fig. 1 and 8, the deodorization mechanism 1 is disposed opposite to the opening side 21 of the can body 2 of the trash can. Further, the deodorization mechanism 1 includes: deodorization clamp 11, drive arrangement 12 and host system.

As shown in fig. 2 and 3, in the present embodiment, the deodorization clip 11 includes: a first movable bar 111, a second movable bar 112, a third movable bar 113, and a fixed bar 114. The first movable rod 111 and the second movable rod 112 are opposite to each other along a first preset linear direction and are arranged in parallel; meanwhile, the third movable bar 113 and the fixed bar 114 are opposite along a second preset linear direction and are arranged in parallel. The first preset linear direction is perpendicular to the second preset linear direction.

Next, as shown in fig. 1, 2, 3 and 4, the driving device 12 is connected to the first movable bar 111 and the third movable bar 113, respectively, and as shown in fig. 2 and 3, the driving device 12 is used for driving the first movable bar 111 and the second movable bar 112 to move relative to each other along a first predetermined linear direction; meanwhile, the driving device 12 is further configured to drive the third movable bar 113 to move toward the insertion direction near the fixed bar 114, so that the first movable bar 111, the second movable bar 112, the third movable bar 113 and the fixed bar 114 can enclose a clamping area 115 for opening or tightening the opening of the garbage bag. It should be noted that, in the present embodiment, the first predetermined linear direction is perpendicular to the second predetermined linear direction, and in practical applications, the first predetermined linear direction may not be perpendicular to the second predetermined linear direction, and an included angle formed between the first predetermined linear direction and the second predetermined linear direction may be any angle.

Finally, as shown in fig. 5, the main control module is further communicatively connected to the driving device 12, and the main control module is configured to receive a drum lid opening instruction or a drum lid closing instruction. When receiving a drum lid closing instruction, the main control module may send a first driving signal to the driving device 12, and when receiving a drum lid opening instruction, the main control module may send a second driving signal to the driving device 12. In practical application, when the driving device 12 receives the first driving signal sent by the main control module, as shown in fig. 3, the first movable rod 111 and the second movable rod 112 can be driven to move toward a direction in which they approach each other, and at the same time, the third movable rod 113 is driven to move toward a direction in which it approaches the fixed rod 114, so that the clamping area 115 is continuously reduced, and the bag opening of the garbage bag 100 can be tightened. On the contrary, when the driving device receives the second driving signal sent by the main control module, as shown in fig. 2, the first movable rod 111 and the second movable rod 112 can be driven to move in a direction away from each other, and at the same time, the third movable rod 113 is driven to move in a direction away from the fixed rod 114, so that the clamping area 115 is continuously enlarged, and thus the opening of the garbage bag 100 can be opened, so as to implement the garbage throwing by the user.

As can be seen from the above, the first movable rod 111, the second movable rod 112, the third movable rod 113, and the fixing rod 14 of the anti-odor clamp 11 can tighten and open the opening of the trash bag 100, so that the user can throw the trash without being affected, and meanwhile, the odor generated by the trash in the trash bag 100 can be effectively prevented from overflowing from the bag, so that the user can feel better.

Specifically, in the present embodiment, as shown in fig. 4, the driving device 12 includes: a driving assembly 121 and a transmission assembly 122. The driving component 121 is in communication connection with the main control module, and the driving component 121 is configured to receive a first driving signal or a second driving signal. In addition, the transmission assembly 122 is connected to the driving assembly 121, and meanwhile, the transmission assembly 122 is also connected to the first movable bar 111, the second movable bar 112, the third movable bar 113, and the fixed bar 114. In practical applications, as shown in fig. 2 and 3, the driving assembly 121 may drive the first movable bar 111 and the second movable bar 112 to move relative to each other along a first predetermined linear direction through the transmission assembly 122. Meanwhile, the driving assembly 121 drives the third movable rod 113 to move along the second preset linear direction through the transmission assembly 122.

Further, in the present embodiment, as shown in fig. 4, the driving unit 121 includes: motor 1211, reduction gear 1212. And the transmission assembly 122 includes: a first master timing wheel 1221, a first slave timing wheel 1222, a first timing belt 1223, a second master timing wheel 1224, a second slave timing wheel 1225, and a second timing belt 1226. The motor 1211 is in communication connection with the main control module, so that the motor 1211 can receive the first driving signal or the second driving signal sent by the main control module. Next, as shown in fig. 2, 3 and 4, a first master synchronizing wheel 1221 is coaxially connected to an output shaft 12121 of the speed reducer 1212, and a first slave synchronizing wheel 1222 is disposed opposite to the first master synchronizing wheel 1221 in a first predetermined linear direction, and at the same time, a first synchronizing belt 1223 connects the first master synchronizing wheel 1221 and the first slave synchronizing wheel 1222. As shown in fig. 2, 3, and 4, the first timing belt 1223 further includes: a first inner transmission layer 12231 disposed toward the clamping region 115, and a first outer transmission layer 12232 disposed away from the clamping region 115. In addition, as shown in fig. 4, a second master synchronizing wheel 1224 is coaxially connected with an output shaft 12121 of the speed reducer 1212, and a second slave synchronizing wheel 1225 is disposed opposite to the second master synchronizing wheel 1224 in a second preset linear direction, and at the same time, a second synchronizing belt 1226 connects the second master synchronizing wheel 1224 and the second slave synchronizing wheel 1225. As shown in fig. 2 and 3, the second timing belt 1226 further includes: a second inner transmission layer 12261 disposed toward the clamping region 115, and a second outer transmission layer 12262 disposed away from the clamping region 115.

Also, in order to satisfy the relative movement of the first and second

movable bars

111 and 112, as shown in fig. 2 and 3, the first movable bar 111 may be connected to the first outer transmission layer 12232 of the first timing belt 1223, and at the same time, the second movable bar 112 may be connected to the first inner transmission layer 12231 of the first timing belt 1223. In addition, in order to realize the relative movement of the third movable rod 113 and the fixed rod 114, the third movable rod 113 may be connected to the second outer transmission layer 12262 of the second synchronous belt 1226, so that in practical applications, the first master synchronous wheel 1221 and the second master synchronous wheel 1224 may be synchronously driven to rotate by the motor 1211 via the speed reducer 1212, and at the same time, the first synchronous belt 1223 and the second synchronous belt 1226 may respectively drive the first slave synchronous wheel 1222 and the second slave synchronous wheel 1225 to rotate under the rotation movement of the first master synchronous wheel 1221 and the second master synchronous wheel 1224, so that the first movable rod 111 and the second movable rod 112 may perform the relative movement along the first preset linear direction, and at the same time, the third movable rod 113 may move along the second preset linear direction relative to the fixed rod 114, so as to realize the tightening and opening of the bag mouth of the garbage bag 100. Of course, it should be noted that the fixing rod 114 may be connected to the second inner transmission layer 12261 of the second timing belt 1226 in practical applications.

Further, in order to achieve the connection and fixation between the first movable bar 111 and the first timing belt 1223, in the present embodiment, as shown in fig. 6, a first notch 1111 and a first tooth row formed by a combination of a plurality of first teeth 1112 provided in the first notch 1111 may be provided at either end of the first movable bar 111, and the first teeth 1112 in the first tooth row may be sequentially provided in the first predetermined linear direction. In practical applications, as shown in fig. 6, the first tooth row in the first slot 1111 at either end of the first movable bar 111 can be engaged with the first outer transmission layer 12232 of the first synchronous belt 1223. It can be seen that, due to the engagement of the first teeth 1112 and the first outer transmission layer 12232 of the first synchronous belt 1223, the first movable bar 111 can be prevented from slipping when moving relative to the second movable bar 112, thereby improving the accuracy of the first movable bar 111 when moving relative to the second movable bar 112. Similarly, in order to achieve the connection and fixation between the second movable bar 112 and the first synchronous belt 1223, as shown in fig. 7, a second engaging groove 1121 and a second tooth row formed by combining a plurality of second teeth 1122 and provided in the second engaging groove 1121 may be provided at either end of the second movable bar 112, and the second teeth 1122 in the second tooth row may be sequentially provided along the first predetermined straight line direction. In practical applications, as shown in fig. 7, the second tooth rows of the second engaging grooves 1121 at either end of the second movable bar 112 can be engaged with the first inner transmission layer 12231 of the first synchronous belt 1223. It can be seen that, by the engagement of the second teeth 1122 with the first inner transmission layer 12231 of the first timing belt 1223, a slip phenomenon of the second movable bar 112 while moving relative to the first movable bar 111 can be prevented, thereby improving the accuracy when the second movable bar 112 and the first movable bar 111 move relative to each other.

Similarly, in order to achieve the connection fixation between the third movable bar 113 and the second timing belt 1226. In this embodiment, the third movable bar 113 may have the same structural design as the first movable bar 111 and the second movable bar 112, so that the third movable bar 113 can be clamped and fixed to the second outer transmission layer 12262 or the second inner transmission layer 12261 of the second timing belt 1226.

In addition, as a preferable mode, in order to improve the moving performance when the first movable bar 111 and the second movable bar 112 move relative to each other, as shown in fig. 2 and 3, in the present embodiment, the driving device 12 further includes: and a first guide rod 123, wherein the first guide rod 123 is arranged along the first preset linear direction, and the first guide rod 123 is further slidably connected with the first movable rod 111 and the second movable rod 112. It is thus apparent that the first and second

movable bars

111 and 112 can be guided by the first guide bar 123 while moving relative to each other, so that the moving performance of the first and second

movable bars

111 and 112 can be improved. However, in some embodiments, as shown in fig. 2 and 3, two first guide rods 123 are provided, and the two first guide rods 123 are opposite to each other along the second predetermined linear direction and are arranged in parallel, and meanwhile, two ends of the first movable rod 111 and two ends of the second movable rod 112 are slidably connected to the two first guide rods 123, respectively. As a result, the first and second

movable bars

111 and 112 are guided by the two first guide bars 123, and the movement performance when the first and second

movable bars

111 and 112 move relative to each other can be further improved.

Also, in order to improve the moving performance when the third movable bar 113 and the fixed bar 114 move relative to each other, as shown in fig. 2 and 3, in the present embodiment, the driving device 12 further includes: and a second guide bar 124, wherein the second guide bar 124 is arranged along a second predetermined linear direction, and the second guide bar 124 is further slidably connected to the third movable bar 113. It is thus apparent that the second guide bar 124 can guide the third movable bar 113 while moving relative to the fixed bar 114, thereby improving the moving performance of the third movable bar 113. However, in some embodiments, as shown in fig. 2 and 3, two second guide rods 124 are provided, and the two second guide rods 124 are opposite to each other along the first predetermined linear direction and are arranged in parallel, and meanwhile, two ends of the third movable rod 113 are slidably connected to the two second guide rods 124, respectively. As can be seen from this, the movement performance of the third movable bar 113 when moving relative to the fixed bar 114 can be further improved by guiding the third movable bar 113 by the two second guide bars 124.

In order to slidably couple the first movable rod 111 and the first guide rod 123, in the present embodiment, as shown in fig. 6, a first guide hole 1113 through which one of the first guide rods 123 can be inserted may be provided at one end of the first movable rod 111, a second guide hole 1114 through which the other of the first guide rods 123 can be inserted may be provided at the other end of the first movable rod 111, and the two first guide rods 123 may be inserted into the first guide hole 1113 and the second guide hole 1114 of the first movable rod 111, respectively, thereby slidably coupling the first movable rod 111 and the two first guide rods 123, respectively. Similarly, in order to realize the sliding connection between the second movable bar 112 and the first guide bar 123, the second movable bar 112 may have the same structure as the first movable bar 111, and thus, detailed description thereof will be omitted in this embodiment.

In order to slidably couple the third movable bar 113 and the two second guide bars 124, the third movable bar 113 may have the same configuration as the first movable bar 111, and thus the third movable bar 113 and the second guide bars 124 may be slidably coupled. In the present embodiment, the structure of the third movable bar 113 and the fixed bar 114 will not be described in detail.

Furthermore, it should be noted that, as a preferable mode, in order to improve the sealing performance of the odor-resistant clamp 11 to the garbage bag 100 after the bag opening of the garbage bag 100 is tightened, in the present embodiment, as shown in fig. 9, the odor-resistant clamp 11 further includes: the first flexible layer 13 and the second flexible layer 14, and the first flexible layer 13 is disposed on a side of the first movable rod 111 opposite to the second movable rod 112, and the second flexible layer 14 is disposed on a side of the third movable rod 113 opposite to the fixed rod 114, so that after the anti-odor clamp 11 finishes tightening the bag mouth of the garbage bag 100, the sealing performance of the bag mouth during tightening can be improved through the first flexible layer 13 and the second flexible layer 14. Of course, in practical applications, the first flexible layer 13 may be disposed on the side of the second movable bar 112 opposite to the first movable bar 111, and the second flexible layer 14 may be disposed on the side of the fixed bar 114 opposite to the third movable bar 113. In addition, as a preferable scheme, in some embodiments, two first flexible layers 13 and two second flexible layers 14 may be provided, and one of the first flexible layers 13 is provided on one side of the first movable bar 111 opposite to the second movable bar 112, and the other first flexible layer 13 is provided on one side of the second movable bar 112 opposite to the first movable bar 111, and meanwhile, one of the second flexible layers 14 is provided on one side of the third movable bar 113 opposite to the fixed bar 114, and the other second flexible layer 14 is provided on one side of the fixed bar 114 opposite to the third movable bar 113, so that the sealing performance of the anti-odor clamp 11 when the mouth of the garbage bag 100 is tightened can be further improved through the two first flexible layers 13 and the two second flexible layers 14. In the present embodiment, for example, a flexible member such as a rubber layer or a silicone layer may be used for the first flexible layer 13 and the second flexible layer 14, but other flexible members may be used.

Note that, in the present embodiment, as shown in fig. 9, the deodorization clip 11 further includes: the first cushion 14 is provided on the first movable rod 111 on the side opposite to the second movable rod 112, and the first cushion 14 is provided on the second movable rod 112. In addition, in this embodiment, the first buffer material 14 may be made of buffer cotton, buffer glue, a spring, or the like, and the first buffer material 14 may prevent the garbage bag 100 from being damaged due to an excessively high moving speed when the first movable rod 111 moves in the direction of the second movable rod 112, thereby protecting the garbage bag 100. In addition, in the present embodiment, the first cushion material 14 is described only by way of example as being provided on the side of the first movable bar 111 with respect to the second movable bar 112, but in actual use, the first cushion material 14 may be provided on the side of the second movable bar 112 with respect to the first movable bar 111, however, as a preferable aspect, in some embodiments, the first cushion material 14 may be provided on the side of the first movable bar 111 with respect to the second movable bar 112 and on the side of the second movable bar 112 with respect to the first movable bar 111.

Example two

The second embodiment of the present invention relates to a deodorization mechanism for a trash can, and the second embodiment is further improved on the basis of the first embodiment, and the main improvement thereof lies in that, as shown in fig. 10, the deodorization mechanism of the present embodiment further includes: the first detection module 15 and the second detection module 16, and as shown in fig. 11, the first detection module 15 and the second detection module 16 may be respectively in communication connection with the main control module.

As shown in fig. 10 and 11, the first detection module 15 is configured to detect whether the first movable bar 111 or the second movable bar 112 moves to a first preset position when the first movable bar 111 and the second movable bar 112 move toward each other, that is, whether the first movable bar 111 and the second movable bar 112 move to a closed position. And, when the first detecting module 15 detects that the first movable bar 111 or the second movable bar 112 moves to the first preset position, the first detecting module 15 may send a first detecting signal to the main control module. And the main control module is used for turning off the motor 1211 of the driving assembly 121 when receiving the first detection signal.

In addition, as shown in fig. 10 and 11, the second detection module 16 is configured to detect whether the first movable bar 111 moves to a second preset position when the first movable bar 111 and the second movable bar 112 move in a direction away from each other, that is, whether the first movable bar 111 moves out of the area of the opening side 21 of the tub 2, and when the second detection module 16 detects that the first movable bar 111 moves to the second preset position, the second detection module 16 may send a second detection signal to the main control module. And the main control module is used for turning off the motor 1211 of the driving component 121 when receiving the second detection signal. Certainly, it should be noted that, in actual application, the second detecting module 16 may also send a second detecting signal to the main control module by detecting whether the second movable rod 112 reaches the second preset position.

In addition, it should be noted that the first detection module 15 and the second detection module 16 used in the present embodiment are both photoelectric sensors, but in practical applications, other types of sensors may be used for the first detection module 15 and the second detection module 16, and in the present embodiment, the types of the first detection module 15 and the second detection module 16 are not specifically limited.

As can be seen from the above description, the present embodiment can enable the main control module to effectively control the motor 1211 of the driving assembly 121 by detecting the position of the first movable rod 111 or the second movable rod 112 through the first detecting module 15 and the second detecting module 16.

As an alternative, as shown in fig. 12, the deodorization mechanism according to the present embodiment may include: the third detection module 17 and the fourth detection module 18, and as shown in fig. 13, the third detection module 17 and the fourth detection module 18 may be respectively in communication connection with the main control module.

As shown in fig. 12 and 13, the third detecting module 17 is configured to detect whether the third movable bar 113 moves to a third preset position when the third movable bar 113 moves towards a direction close to the fixed bar 114, that is, whether the third movable bar 113 moves to a position where the third movable bar 113 is folded with the fixed bar 114. And, when the third detecting module 17 detects that the third movable rod 113 moves to the third preset position, the third detecting module 17 may send a third detecting signal to the main control module. And the main control module is used for turning off the motor 1211 of the driving component 121 when receiving the third detection signal.

In addition, as shown in fig. 12 and 13, the fourth detecting module 18 is configured to detect whether the third movable rod 113 moves to a fourth preset position when the third movable rod 113 moves away from the fixed rod 114, that is, detect whether the third movable rod 113 moves out of the area of the opening side 21 of the tub 2, and when the fourth detecting module 18 detects that the third movable rod 113 moves to the fourth preset position, the fourth detecting module 18 may send a fourth detecting signal to the main control module. And the main control module is used for turning off the motor 1211 of the driving assembly 121 when receiving the fourth detection signal.

It should be noted that, in the present embodiment, the third detection module 17 and the fourth detection module 18 are both photoelectric sensors, but in practical applications, other types of sensors may be used for the third detection module 17 and the fourth detection module 18, and in the present embodiment, the types of the third detection module 17 and the fourth detection module 18 are not specifically limited.

As can be seen from the above description, the present embodiment detects the position of the third movable rod 113 or the fixed rod 114 through the third detection module 17 and the fourth detection module 18, so that the main control module can also effectively control the motor 1211 of the driving assembly 121.

EXAMPLE III

The third embodiment of the present invention relates to a deodorization mechanism for a trash can, and the third embodiment is substantially the same as the first embodiment, and the main difference is that in the first embodiment, the movement of the first movable bar 111, the second movable bar 112, the third movable bar 113, and the fixed bar 114 is realized by only one motor 1211 for driving the same. In the present embodiment, as shown in fig. 14 and 15, the driving device 12 includes: a first drive assembly 125, a first transmission assembly 126, a second drive assembly 127, and a second transmission assembly 128. As shown in fig. 16, the first driving component 125 and the second driving component 127 are both communicatively connected to the main control module, so that the first driving component 125 and the second driving component 127 are configured to receive the first driving signal or the second driving signal.

In addition, as shown in fig. 14, the first transmission assembly 126 is connected to the first driving assembly 125, the first movable bar 111 and the second movable bar 112, respectively, such that the first driving assembly 125 can drive the first movable bar 111 and the second movable bar 112 to move relative to each other along the first preset linear direction through the first transmission assembly 126. Meanwhile, the second transmission assembly 128 is respectively connected with the second driving assembly 127 and the third movable bar 113, so that the second driving assembly 127 can drive the third movable bar 113 to move along a second preset linear direction relative to the fixed bar 114 through the second transmission assembly 128.

Specifically, in the present embodiment, as shown in fig. 15, the first driving assembly 125 includes: a first motor 1251, a first decelerator 1252. Wherein, first motor 1251 is connected with the main control module communication for first motor 1251 can receive the first drive signal or the second drive signal that main control module sent, secondly, first reduction gear 1252 is connected with the output of first motor 1251, and simultaneously, first drive assembly 126 and the first output shaft 12521 coaxial coupling of first reduction gear 1252, thereby make first drive assembly 126 can be under first motor 1251 through the drive of first reduction gear 1252, drive first movable rod 111 and second movable rod 112 towards the direction that is close to each other or keeps away from each other, carry out linear motion.

Also, as shown in fig. 15, the second driving assembly 127 includes: the second motor 1271 and the second reducer 1272, wherein the second motor 1271 is in communication connection with the main control module, so that the second motor 1271 can receive the first driving signal or the second driving signal sent by the main control module, then the second reducer 1272 is connected with the output end of the second motor 1271, and meanwhile, the second transmission assembly 128 is coaxially connected with the second output shaft 12721 of the second reducer 1272, so that the second transmission assembly 128 can drive the third movable rod 113 to perform linear motion relative to the fixed rod 114 under the driving of the second motor 1271 through the second reducer 1272.

Further, in the present embodiment, in order to enable the first transmission assembly 126 to bring the first movable rod 111 and the second movable rod 112 into relative movement with respect to each other along the first preset linear direction, as shown in fig. 14 and 15, the first transmission assembly 126 includes: a first master synchronizing wheel 1261, a first slave synchronizing wheel 1262, and a first synchronizing belt 1263. Wherein the first master synchronizing wheel 1261 is coaxially connected to the second output shaft 12521 of the first decelerator 1252, and the first slave synchronizing wheel 1262 is disposed opposite to the first master synchronizing wheel 1261 in the first predetermined linear direction, and the first synchronizing belt 1263 connects the first master synchronizing wheel 1261 and the first slave synchronizing wheel 1262, and as shown in fig. 14 and 15, the first synchronizing belt 1263 has: a first inner transmission layer 12631 disposed toward the clamping region 115, and a first outer transmission layer 12632 disposed away from the clamping region 115.

Similarly, in order to enable the second transmission assembly 128 to drive the third movable rod 113 to perform a linear motion relative to the fixed rod 114, as shown in fig. 14 and 15, the second transmission assembly 128 includes: a second master synchronizing wheel 1281, a second slave synchronizing wheel 1282 and a second synchronous belt 1283. Wherein the second master timing wheel 1281 is coaxially connected to the second output shaft 12721 of the second reducer 1272, and the second slave timing wheel 1282 is disposed opposite to the second master timing wheel 1281 in the second preset linear direction, and at the same time, the second timing belt 1283 connects the second master timing wheel 1281 and the second slave timing wheel 1282, and, as shown in fig. 8, the second timing belt 1283 has: a second inner drive layer 12831 disposed toward the clamping region 115, and a second outer drive layer 12832 disposed away from the clamping region 115.

In order to enable the first transmission assembly 126 to drive the first movable rod 111 and the second movable rod 112 to move relative to each other along the first predetermined linear direction, as shown in fig. 14, the first movable rod 111 is connected to the first inner transmission layer 12631 of the first synchronous belt 1263, and the second movable rod 112 is connected to the first outer transmission layer 12632 of the first synchronous belt 1263. In practical applications, as shown in fig. 15, the first motor 1251 drives the first master synchronizing wheel 1261 to rotate via the first speed reducer 1252, and the second slave synchronizing wheel 1262 is driven to rotate by the first timing belt 1263, so that the first movable rod 111 and the second movable rod 112 can move linearly in a direction away from each other or in a direction approaching each other by the first timing belt 1263.

Similarly, in this embodiment, in order to enable the second transmission assembly 128 to drive the third movable rod 113 to move linearly relative to the fixed position, as shown in fig. 14, the third movable rod 113 may be connected to a second inner transmission layer 12831 of a second timing belt 1283. Thus, in practical application, as shown in fig. 6, the second motor 1271 drives the second master synchronizing wheel 1281 to rotate through the second reducer 1272, and then the second slave synchronizing wheel 1282 is driven by the second synchronous belt 1283 to rotate, so that the third movable rod 113 can move in a direction close to the fixed rod 114 or in a direction away from the fixed rod 114 under the transmission of the second synchronous belt 1283. In this embodiment, the third movable bar 113 and the second inner transmission layer 12831 of the second timing belt 1283 are merely connected, but in actual use, the fixed bar 114 and the second outer transmission layer 12832 of the second timing belt 1283 may be connected,

further, it is preferable that the first and second

movable bars

111 and 112 do not interfere with the third movable bar 113 in order to enable the first and second

movable bars

111 and 112 to move relatively and the third movable bar 113 to move relative to the fixed bar 114. The first movable bar 111 and the second movable bar 112 are slidably connected to the third movable bar along the first predetermined linear direction, and the third movable bar 113 is slidably connected to the first movable bar 111 and the second movable bar 112 along the second predetermined linear direction.

Specifically, as shown in fig. 17, the first movable bar 111 is provided with a first slide way 1115 along the second preset linear direction, meanwhile, the second movable bar 112 is provided with a second slide way 1123 along the second preset linear direction, and the third movable bar 113 is arranged through the first slide way 1115 and the second slide way 1123. It can be seen that the first movable bar 111 can freely move along the first preset straight line direction through the first slide way 1115 and the second slide way 1123, and the third movable bar 113 can freely slide along the second preset straight line direction. As an alternative, in some embodiments, as shown in fig. 18, the third movable bar 113 is provided with a third slide channel 1131 along the first preset linear direction, and the first movable bar 111 and the second movable bar 112 are respectively inserted into the third slide channel 1131. In this way, the relative movement of the first and second

movable bars

111 and 112 in the first predetermined linear direction and the movement of the third movable bar 113 in the second predetermined linear direction can be similarly achieved.

Example four

The fourth embodiment of the present invention relates to a deodorization mechanism for a trash can, and the fourth embodiment is further improved on the basis of the third embodiment, and the main improvement thereof lies in that, as shown in fig. 19, the deodorization mechanism 1 of the present embodiment further includes: the first detection module 15, the second detection module 16, the third detection module 17, and the fourth detection module 18, and as shown in fig. 20, the first detection module 15, the second detection module 16, the third detection module 17, and the fourth detection module 18 may be respectively in communication connection with the main control module.

When the first movable bar 111 and the second movable bar are moved in a direction approaching each other, as shown in fig. 19 and 20, it can be detected by the first detecting module 15 whether the first movable bar 111 or the second movable bar 112 is moved to the first preset position, that is, whether the first movable bar 111 and the second movable bar 112 are moved to the closed position. And, when the first detecting module 15 detects that the first movable rod 111 or the second movable rod 112 moves to the first preset position, the first detecting module 15 may send a first detecting signal to the main control module. On the contrary, when the first and second

movable levers

111 and 112 move in a direction away from each other, as shown in fig. 17 and 18, it may be detected by the second detecting module 16 whether the second movable lever 112 moves to a second preset position, that is, whether the second movable lever 112 moves outside the area of the opening side 21 of the tub 2, and when the second detecting module 16 detects that the second movable lever 112 moves to the second preset position, the second detecting module 16 may transmit a second detection signal to the main control module. In addition, the main control module may turn off the first motor 1251 of the first driving assembly 125 when the main control module receives the first detection signal or the second detection signal. Certainly, it should be noted that, in actual application, the second detecting module 16 may also send the second detecting signal to the main control module by detecting whether the first movable rod 112 reaches the second preset position.

Similarly, when the third movable bar 113 moves toward the direction close to the fixed bar 114, as shown in fig. 19 and 20, it can be detected by the third detecting module 17 whether the third movable bar 113 moves to the third preset position, that is, whether the third movable bar 113 moves to the position where it is folded with the fixed bar 114. And, when the third detecting module 17 detects that the third movable rod 113 moves to the third preset position, the third detecting module 17 may send a third detecting signal to the main control module. On the contrary, when the third movable rod 113 moves away from the fixed rod 114, as shown in fig. 19 and 20, it may be detected by the fourth detecting module 18 whether the third movable rod 113 moves to a fourth preset position, that is, whether the third movable rod 113 moves out of the region of the opening side 21 of the tub 2, and when the fourth detecting module 18 detects that the third movable rod 113 moves to the fourth preset position, the fourth detecting module 18 may send a fourth detecting signal to the main control module. In addition, when the main control module receives the third detection signal or the fourth detection signal, the main control module may turn off the second motor 1271 of the second driving assembly 127.

It should be noted that the first detection module 15, the second detection module 16, the third detection module 17, and the fourth detection module 18 used in this embodiment are all photoelectric sensors, but in practical applications, the first detection module 15 and the second detection module 16 may also use other types of sensors, and in this embodiment, the types of the first detection module 15 and the second detection module 16 are not specifically limited.

As can be seen from the above description, in the present embodiment, the detection of the position of the first movable rod 111 or the second movable rod 112 by the first detection module 15 and the second detection module 16 enables the main control module to effectively control the first motor 1251 of the first driving assembly 125. Meanwhile, the detection of the position of the third movable rod 113 by the third detection module 17 and the fourth detection module 18 may enable the main control module to effectively control the second motor 1251 of the second driving assembly 125.

EXAMPLE five

The fifth embodiment of the present invention relates to a trash can, as shown in fig. 21, including: staving 2, rotationally set up bung 3 on staving 2, like first, second, third or fourth embodiment deodorant mechanism 1, control the module, wherein, control the module and be connected with the host system communication, staving 2 has along predetermineeing the axis direction: and an open side 21. Meanwhile, the deodorization mechanism 1 is arranged opposite to the opening side 21 of the garbage can body 2.

In practical application, the control module may be, for example, a control panel integrated with a touch key and/or a physical key, and a user may send a lid opening instruction or a lid closing instruction to the main control module through the control module, and after the main control module receives the lid closing instruction, the main control module may send a first driving signal to the driving device 12, so that the driving device 12 may drive the first movable rod 111 and the second movable rod 112 to move in directions close to each other, and at the same time, further drive the third movable rod 113 to move in a direction close to the fixed rod 114, so that the clamping area 115 is continuously reduced, and thereby the bag opening of the garbage bag 100 may be tightened. On the contrary, after the main control module receives the lid opening instruction, the main control module may send a second driving signal to the driving device 12, and with reference to fig. 1, the driving device 12 may drive the first movable rod 111 and the second movable rod 112 to move in a direction away from each other, and simultaneously drive the third movable rod 113 to move in a direction away from the fixing rod 114, so that the clamping area 115 is continuously enlarged, and thus the mouth of the garbage bag 100 may be opened, so as to implement the garbage throwing by the user.

As can be seen from the above, the first movable rod 111, the second movable rod 112, the third movable rod 113 and the fixing rod 14 of the anti-odor clamp 11 can tighten up and open the opening of the bag opening of the garbage bag 100, so that the odor generated by the garbage in the garbage bag 100 can be effectively prevented from overflowing from the bag body while the garbage is not influenced by a user, and the use experience of the user can be improved.

It will be understood by those skilled in the art that the foregoing embodiments are specific to implementations of the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in practice.

Claims

1. The utility model provides a deodorant mechanism of garbage bin, its characterized in that sets up in the opening side of the staving of garbage bin, deodorant mechanism includes:

a deodorization clip; deodorant clamp includes: the first movable rod and the second movable rod are arranged oppositely and parallelly along the first preset linear direction; deodorant clamp still includes: the third movable rod and the fixed rod are arranged oppositely and parallelly along the second preset linear direction; the first preset linear direction is perpendicular to the second preset linear direction;

the driving device is respectively connected with the first movable rod, the second movable rod and the third movable rod; the driving device is used for driving the first movable rod and the second movable rod to move relative to each other along the first preset linear direction; the driving device is also used for driving the third movable rod to move relative to the fixed rod; the first movable rod, the second movable rod, the third movable rod and the fixed rod enclose a clamping area for opening or tightening a bag opening of the garbage bag;

2. The odor preventing mechanism for a trash can of claim 1, wherein the driving means comprises:

the driving component is in communication connection with the main control module and is used for receiving the first driving signal or the second driving signal;

3. The odor preventing mechanism of a trash can of claim 2, wherein the drive assembly comprises:

the speed reducer is connected with the output end of the motor; wherein, the transmission assembly is connected with the output shaft of the speed reducer.

4. The odor preventing mechanism of a trash can of claim 3, wherein the transmission assembly comprises:

5. The odor-preventing mechanism for a trash can of claim 2, further comprising:

the first detection module is in communication connection with the main control module; the first detection module is used for detecting whether the first movable rod or the second movable rod moves to a first preset position or not when the first movable rod and the second movable rod move towards the direction close to each other; the first detection module is further configured to send a first detection signal to the main control module when detecting that the first movable rod or the second movable rod moves to a first preset position;

6. The odor-resistant mechanism of a trash can of claim 2, further comprising:

7. The odor preventing mechanism of a trash can of claim 1, wherein the driving means comprises:

the first driving assembly and the second driving assembly are in communication connection with the main control module and are used for receiving the first driving signal or the second driving signal;

the first transmission assembly is connected with the first driving assembly; the first transmission assembly is further connected with the first movable rod and the second movable rod;

the second transmission assembly is connected with the second driving assembly; wherein the second transmission assembly is further connected with the third movable rod.

8. The odor preventing mechanism of a trash can of claim 7, wherein the first drive assembly comprises:

the second drive assembly includes:

9. The odor preventing mechanism of a trash can of claim 8, wherein the first transmission assembly comprises:

wherein the first movable bar is connected with the first outer transmission layer of the first synchronous belt, and the second movable bar is connected with the first inner transmission layer of the first synchronous belt;

the second transmission assembly includes:

10. The odor-resistant mechanism of a trash can of claim 7, further comprising:

the first detection module is in communication connection with the main control module; the first detection module is used for detecting whether the first movable rod or the second movable rod moves to a first preset position or not when the first movable rod and the second movable rod move towards the direction of mutual approaching; the first detection module is further configured to send a first detection signal to the main control module when detecting that the first movable rod or the second movable rod moves to a first preset position;

the third detection module is in communication connection with the main control module; the third detection module is used for detecting whether the third movable rod moves to a third preset position or not when the third movable rod moves towards the direction close to the fixed rod; the third detection module is further used for sending a third detection signal to the main control module when the third movable rod is detected to move to a third preset position;

11. The odor preventing mechanism of a trash can of claim 1, wherein the driving device further comprises:

12. The odor-resistant mechanism of a trash can of claim 1, wherein the first movable bar is further slidably connected with the third movable bar along the first predetermined linear direction;

the third movable rod is in the second preset linear direction and is respectively connected with the first movable rod and the second movable rod in a sliding mode.

13. The odor-resistant mechanism of a trash can of claim 1, wherein the odor-resistant clip further comprises:

14. The odor-resistant mechanism of a trash can of claim 1, wherein the odor-resistant clip further comprises:

the first buffer piece is arranged on one side of the first movable rod opposite to the second movable rod or on one side of the second movable rod opposite to the first movable rod;

15. A trash can, comprising:

a barrel body; the staving is along predetermineeing the axis direction, has: an opening side;

the odor-inhibiting mechanism of any one of claims 1-14;

a tub cover for opening or closing an opening side of the tub;