CN212962703U - Three-dimensional blow-drying device for cleaning inner wall of container - Google Patents

Abstract

The three-dimensional blow-drying device for cleaning the inner wall of the container comprises an integral chassis, wherein a bearing bracket is arranged on the integral chassis, a fan, an air duct, a current collecting slip ring, a rotating bearing gear and a rotary reversing air supply mechanism are arranged on the bearing bracket from back to front, and a servo motor drives the rotary reversing air supply mechanism to rotate through the rotating bearing gear; the rotary reversing air supply mechanism comprises an internal air channel switching device and an external blowing rotary blade, and air is output by the fan and then sequentially flows through the air channel, the inside of the collector slip ring, the inside of the rotating bearing gear, the air outlet channel of the air channel switching device of the air channel and is blown out from the air outlet of the external blowing rotary blade. The utility model discloses an above-mentioned structure has reduced workman intensity of labour, provides a simple structure, and convenient to use is effectual is used for the abluent three-dimensional device that weathers of container inner wall.

Description

Three-dimensional blow-drying device for cleaning inner wall of container

Technical Field

The utility model relates to a building engineering construction equipment technical field especially relates to a detachable temporary support device is used in building engineering construction.

Background

Domestic container washing always adopts a manual washing mode as a main mode, and because of the structural characteristics of the container: the single-side door is opened, the inside of the box is closed, the depth is long, the air circulation in the box is poor, the problems of low manual washing efficiency, high labor intensity and the like exist, and particularly, in northern areas, the hot water washing steam of the container is large in winter, the manual operation cannot be performed, and the drying is slow.

Disclosure of Invention

The utility model provides a be used for abluent three-dimensional device that weathers of container inner wall has solved the technical problem that the manual work efficiency that exists among the prior art is low, intensity of labour is big, be not suitable for extreme weather environment.

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

the three-dimensional blow-drying device for cleaning the inner wall of the container comprises an integral chassis, wherein a bearing bracket is arranged on the integral chassis, a fan, an air duct, a current collecting slip ring, a rotating bearing gear and a rotary reversing air supply mechanism are arranged on the bearing bracket from back to front, and a servo motor drives the rotary reversing air supply mechanism to rotate through the rotating bearing gear; the rotary reversing air supply mechanism comprises an internal air channel switching device and an external blowing rotary blade, and air is output by the fan and then sequentially flows through the air channel, the inside of the collector slip ring, the inside of the rotating bearing gear, the air outlet channel of the air channel switching device of the air channel and is blown out from the air outlet of the external blowing rotary blade.

The air duct switching device comprises an air delivery pipe and an air duct switching pipe, the air delivery pipe is fixedly connected with the blowing rotating blades, and the air duct switching pipe is sleeved inside the air delivery pipe.

The pipe wall of the air conveying pipe consists of the pipe wall of the air conveying pipe and an air outlet of the air conveying pipe, the air conveying pipe is divided into a front section and a rear section, the pipe wall of the air conveying pipe and the air outlet of the air conveying pipe in each section are distributed at intervals of 45 degrees, the pipe wall of the air conveying pipe in the middle of the front section and the rear section corresponds to the pipe wall of the air conveying pipe, and the air outlet of the air conveying pipe corresponds to the air.

The blowing rotary blade is composed of a plurality of blowing blades, and the position of each blowing blade corresponds to the air outlets of the front air delivery pipe and the rear air delivery pipe in an angle.

Two air channels are arranged inside the blowing blades, and an air channel baffle is arranged between the two air channels; one air channel starts from the air outlet of the air conveying pipe at the front section and outputs to the air outlet at the front end of the blowing blade, and the other air channel starts from the air outlet of the air conveying pipe at the rear section and outputs to the air outlet at the side surface of the blowing blade.

One end of the air duct baffle is arranged at the outer vertex angle of the front section of the fan blade, and the other end of the air duct baffle is arranged at the junction of the air outlets of the front air delivery pipe and the rear air delivery pipe.

The air duct switching tube wall consists of a switching tube wall and a switching tube air outlet, the air duct switching tube is divided into a front section and a rear section, and the switching tube wall and the switching tube air outlet in each section are distributed at intervals of 45 degrees; the pipe wall of the switching pipe and the air outlet of the switching pipe between the front section and the rear section are distributed in a staggered mode.

The air duct switching tube is driven by a servo motor to rotate through a gear.

And the bottom of the integral chassis is provided with a travelling wheel.

The utility model has the advantages that:

the utility model provides a three-dimensional blow-drying device for cleaning the inner wall of the container through the structure, and adopts the blow-drying mode of air outlet rotation and air outlet switching according to the mechanical characteristics of the container; after the inside of the container is cleaned, the blow-drying system can remove residual moisture on the wall and accumulated water on the bottom of the container in an all-around dead angle-free manner, so that all-season washing is realized, and the washing efficiency is improved.

Drawings

Fig. 1 is a schematic diagram of the external structure of the present invention.

Fig. 2 is an exploded view of fig. 1.

Fig. 3 is an exploded view of the rotary reversing air supply mechanism.

Fig. 4 is a schematic view of the wind direction inside the blowing blade.

Fig. 5 is a bottom view of the blowing blade.

Reference numbers in the figures: the device comprises a rotary reversing air supply mechanism 1, a rotary reversing air supply mechanism 1-1 air supply pipe, a pipe wall of a 1-1-1 air supply pipe, an air outlet of a 1-1-2 air supply pipe, a 1-2 air duct switching pipe, a pipe wall of a 1-2-1 switching pipe, an air outlet of a 1-2-2 switching pipe, a 1-3 air blowing rotating blade, a 1-3-1 fan blade, a 1-3-2 air duct baffle, a 2 rotating bearing gear, a 3 current collecting sliding ring, a 4 bearing support, 5 integral base plates, 6 air ducts and 7 fans.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

A three-dimensional device that weathers for container inner wall washs, including whole chassis 5, 5 bottoms on whole chassis are equipped with the walking wheel, are equipped with bearing bracket 4 on the whole chassis 5, on the bearing bracket, by back to preceding fan 7, wind channel 6, current collection sliding ring 3, rolling bearing gear 2 and rotatory switching-over mechanism 1 of supplying gas.

The rotary reversing air supply mechanism 1 comprises an internal air channel switching device and external blowing rotary blades 1-3, the air channel switching device comprises an air conveying pipe 1-1 and an air channel switching pipe 1-2, the air conveying pipe 1-1 is fixedly connected with the blowing rotary blades 1-3, and the air channel switching pipe 1-2 is sleeved inside the air conveying pipe 1-1.

The pipe wall of the air delivery pipe 1-1 consists of an air delivery pipe wall 1-1-1 and an air delivery pipe outlet 1-1-2, the air delivery pipe 1-1 is divided into a front section and a rear section, the air delivery pipe wall 1-1-1 and the air delivery pipe outlet 1-1-2 in each section are distributed at intervals of 45 degrees, the air delivery pipe wall 1-1-1 and the air delivery pipe wall 1-1-1 in the middle of the front section and the rear section correspond to each other in position, and the air delivery pipe outlet 1-1-2 correspond to each other in position.

The tube wall of the air duct switching tube 1-2 consists of a switching tube wall 1-2-1 and a switching tube air outlet 1-2-2, the air duct switching tube 1-2 is divided into a front section and a rear section, and the switching tube wall 1-2-1 and the switching tube air outlet 1-2-2 in each section are distributed at intervals of 45 degrees; the pipe wall 1-2-1 of the switching pipe and the air outlet 1-2-2 of the switching pipe are distributed in a staggered mode between the front section and the rear section.

The air channel switching tube 1-2 is driven to rotate by a servo motor, the servo motor is arranged in the air delivery tube 1-1, and the servo motor drives the air channel switching tube 1-2 by a rotating mechanism.

Specifically, the air channel switching tube 1-2 can be in gear transmission, a disc gear is arranged on the air channel switching tube 1-2 and is meshed with a servo motor output gear on the air conveying tube 1-1, and when the servo motor rotates, the air channel switching tube 1-2 and the air conveying tube 1-1 rotate relatively, so that the air channel switching effect is achieved.

Specifically, the servo motor can be arranged on the outer wall of the air conveying pipe 1-1, the output gear of the motor exceeds the end part of the air conveying pipe 1-1, the disc gear is arranged on the end part of the air channel switching pipe 1-2, and the output gear of the servo motor is meshed with the disc gear. And can be arranged at other positions according to actual needs. The transmission method used here is a common motor transmission method, and therefore, will not be described in detail. When the servo motor does not act, the air channel switching tube 1-2 and the air delivery tube 1-1 rotate synchronously due to the friction between the outside of the air channel switching tube 1-2 and the inside of the air delivery tube 1-1.

Two servo motors are arranged in the structure, one servo motor is responsible for driving the blowing rotary blades 1-3 to rotate, and when the blowing rotary blades 1-3 rotate, the internal air delivery pipes 1-1 and the air channel switching pipes 1-2 rotate synchronously with the blowing rotary blades 1-3. And the other servo motor is responsible for driving the air channel switching tube 1-2 and the air conveying tube 1-1 to rotate relatively when the air channel needs to be switched, and the rotation angle is 45 degrees.

The blowing rotary blade 1-3 consists of a plurality of blowing blades 1-3-1, and the position of each blowing blade 1-3-1 corresponds to the air outlets 1-1-2 of the front air conveying pipe and the rear air conveying pipe at an angle. Two air channels are arranged inside the fan blade 1-3-1, and an air channel baffle 1-3-2 is arranged between the two air channels; one air channel starts from the air outlet 1-1-2 of the air conveying pipe at the front section to the air outlet at the front end of the blowing blade 1-3-1, and the other air channel starts from the air outlet 1-1-2 of the air conveying pipe at the rear section to the air outlet at the side surface of the blowing blade 1-3-1. One end of the air duct baffle 1-3-2 is arranged at the external vertex angle of the front section of the blowing blade 1-3-1, and the other end is arranged at the junction of the air outlets 1-1-2 of the front air delivery pipe and the rear air delivery pipe.

The wind output by the fan 7 sequentially passes through the wind channel 6, the inside of the collector slip ring 3, the inside of the rotating bearing gear 2, the wind channel of the wind channel switching device and is blown out from the wind outlets of the external blowing rotating blades 1-3.

The servo motor drives the rotary reversing air supply mechanism 1 to rotate through the rotary bearing gear 2, and the collector slip ring 3 is an electrical component responsible for communicating the rotating body and conveying energy and signals. The slip ring 3 is a conventional part in the art, is usually installed at the rotation center of the equipment, and mainly consists of two parts, namely a rotating part and a static part. The rotating part is connected with the rotating structure of the equipment and rotates along with the rotating structure, and the static part is connected with the energy source of the fixed structure of the equipment. The slip ring integrally depends on an elastic lapping principle, a rolling lapping principle or a sealing principle, an ingenious motion structure and sealing structure design, precise part manufacturing and matching, reasonable material selection and the like, so that a stable and reliable rotary communication system is formed. The slip ring can provide power energy for the rotating body as long as the slip ring is attached to equipment rotating infinitely, so that the rotating body can perform other motions or detect the working condition in a rotating state while performing the infinite rotation motion. The rotating bearing gear 2 and the slip ring 3 are both in a common existing structure, and the servo motor drives the rotating bearing gear 2 to drive the rotating part to rotate in a common transmission mode, so that detailed description is omitted in the patent.

The working process is as follows:

the device firstly walks to the innermost part of the container, starts the fan, utilizes the air channel switching device of the servo mechanism to blow air from the air outlet at the front end of the whole device, and simultaneously utilizes the servo motor to drive the whole air channel switching tube 1-2 to achieve the effect of blowing air in a rotating way at the front end. After the process is carried out for a period of time, the air channel switching pipe 1-2 is rotated for 45 degrees by utilizing the servo motor to rotate, so that air is blown from the side air outlet of the rotary reversing air supply mechanism to achieve the effect of rotating and blowing the air to the side wall 360 of the container, the side air outlet is of a twisted structure, a certain angle is formed between the air outlet and the integral rotating axis line of the rotary reversing air supply mechanism, and the structure is matched with the integral rotating direction to drive water out of the container. The whole device moves outwards along with the process, and when the wind speed reaches a certain speed, the water is driven and dried, so that the effect of drying the water in the three-dimensional space of the container is achieved.

The rotary reversing air supply mechanism realizes the change of blowing air to the front part and the side wall of the container, and rotates the air channel while blowing air to the front part or the side wall, so that all areas of the front part and the side wall can be blown by the air.

And the third figure is a rotary reversing air supply mechanism which mainly adopts dislocation and rotation transformation. Fig. three is an exploded view of the component 1 of fig. two. Wherein, the air duct switching tube 1-2 is sleeved in the air delivery pipe 1-1 and connected through a bearing to form a concentric device, and the blowing rotary blade 1-3 is welded in the air delivery pipe 1-1.

The structure has two states:

as shown in fig. 3, in the first state, air flows through the four air outlets on the left side of the air duct switching tube 1-2, the four air outlets on the left side of the air delivery tube 1-1, and the four air outlets at the front end of the blowing rotary blade 1-3, and then forward blowing is performed;

in the second state, air flows through the four air outlets on the right side of the air duct switching tube 1-2, the four air outlets on the right side of the air delivery tube 1-1 and the four air outlets on the side surface of the blowing rotary blade 1-3, and then the air is blown to the periphery. Wherein, the air channel switching tube 1-2 has a phase angle of 45 degrees in the first state and the second state, and the state can be switched every 45 degrees of rotation of the air channel switching tube 1-2, so as to achieve the effect of reversing air supply.

The fourth figure is a sectional view of the fan blade 1-3-1, and can be seen that two air duct middle air duct baffles 1-3-2 are arranged at intervals, one outlet is forward, and the other outlet is upward. Preferably, the fan-shaped air duct can also be arc-shaped at the side front end air outlet so as to reduce the wind resistance.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (9)

1. A three-dimensional device that weathers for container inner wall is abluent, its characterized in that: the air conditioner comprises an integral chassis (5), wherein a bearing support (4) is arranged on the integral chassis (5), a fan (7), an air duct (6), a current collecting slip ring (3), a rotating bearing gear (2) and a rotary reversing air supply mechanism (1) are arranged on the bearing support from back to front, and a servo motor drives the rotary reversing air supply mechanism (1) to rotate through the rotating bearing gear (2); the rotary reversing air supply mechanism (1) comprises an internal air channel switching device and external blowing rotary blades (1-3), and air is output by a fan (7) and then sequentially flows through an air channel (6), the interior of the current collecting slip ring (3), the interior of the rotating bearing gear (2), an air outlet channel of the air channel switching device and an air outlet of the external blowing rotary blades (1-3) to be blown out.

2. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 1, wherein: the air channel switching device comprises an air delivery pipe (1-1) and an air channel switching pipe (1-2), wherein the air delivery pipe (1-1) is fixedly connected with a blowing rotating blade (1-3), and the air channel switching pipe (1-2) is sleeved inside the air delivery pipe (1-1).

3. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 2, wherein: the pipe wall of the air delivery pipe (1-1) consists of an air delivery pipe wall (1-1-1) and an air delivery pipe outlet (1-1-2), the air delivery pipe (1-1) is divided into a front section and a rear section, the air delivery pipe wall (1-1-1) and the air delivery pipe outlet (1-1-2) in each section are distributed at intervals of 45 degrees, the positions of the air delivery pipe wall (1-1-1) and the air delivery pipe wall (1-1-1) in the middle of the front section and the rear section correspond, and the positions of the air delivery pipe outlet (1-1-2) and the air delivery pipe outlet (1-1-2) correspond.

4. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 3, wherein: the blowing rotary blade (1-3) is composed of a plurality of blowing blades (1-3-1), and each blowing blade (1-3-1) corresponds to the front and rear air conveying pipe air outlets (1-1-2) in an angle.

5. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 4, wherein: two air channels are arranged inside the fan blade (1-3-1), and an air channel baffle (1-3-2) is arranged between the two air channels; one air channel starts from the air outlet (1-1-2) of the air conveying pipe at the front section and outputs to the air outlet at the front end of the blowing blade (1-3-1), and the other air channel starts from the air outlet (1-1-2) of the air conveying pipe at the rear section and outputs to the air outlet at the side surface of the blowing blade (1-3-1).

6. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 5, wherein: one end of the air duct baffle (1-3-2) is arranged at the outer vertex angle of the front section of the blowing blade (1-3-1), and the other end is arranged at the junction of the air outlets (1-1-2) of the front air delivery pipe and the rear air delivery pipe.

7. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 2, wherein: the air duct switching tube (1-2) is characterized in that the tube wall of the air duct switching tube (1-2-2) consists of a switching tube wall (1-2-1) and a switching tube air outlet (1-2-2), the air duct switching tube (1-2) is divided into a front section and a rear section, and the switching tube wall (1-2-1) and the switching tube air outlet (1-2-2) in each section are distributed at intervals of 45 degrees; the pipe wall (1-2-1) of the switching pipe and the air outlet (1-2-2) of the switching pipe are distributed in a staggered mode between the front section and the rear section.

8. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 7, wherein: the air channel switching tube (1-2) is driven by a servo motor to rotate through a gear.

9. The three-dimensional drying device for cleaning the inner wall of the container as claimed in claim 1, wherein: the bottom of the integral chassis (5) is provided with a travelling wheel.

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