CN214683180U - Rotary shuttle environment-friendly type semi-automatic rotary washing machine - Google Patents

Abstract

The utility model relates to the technical field of rotating shuttle cleaning devices, in particular to an environment-friendly semi-automatic rotating and washing machine for a rotating shuttle, which comprises a main body bracket and an oil pool arranged on the upper part of the main body bracket; a rotating shaft is arranged in the oil pool; a driving mechanism for driving the rotating shaft to rotate is arranged in the main body bracket; the rotating shaft is provided with at least one supporting arm; one end of the support arm, which is far away from the rotating shaft, is provided with a clamping mechanism for mounting the rotating shuttle, and the clamping mechanism comprises a core rod which is arranged on the support arm and used for inserting an outer shuttle of the rotating shuttle and a support column which is used for inserting an inner shuttle of the rotating shuttle; the support is provided with a gear; and the upper wall of the oil pool is fixedly connected with a gear ring section which is coaxial with the rotating shaft, wherein the gear is meshed with the gear ring section. The utility model arranges the core rod for installing the outer shuttle of the rotating shuttle and the support column for installing the inner shuttle of the rotating shuttle, and arranges the oil outlet channel in the core rod; therefore, the oil can enter the interior of the rotating shuttle through the oil outlet channel to clean the interior of the rotating shuttle.

Description

Rotary shuttle environment-friendly type semi-automatic rotary washing machine

Technical Field

The utility model relates to a rotating shuttle belt cleaning device technical field especially relates to a semi-automatic machine of washing that changes of rotating shuttle environment-friendly.

Background

The rotating shuttle is a part composed of parts such as an outer shuttle and an inner shuttle with irregular shapes, a guide rail of the outer shuttle and a guide rail groove of the inner shuttle rotate at a relatively high speed during working, the guide rail and the guide rail groove of the inner shuttle are relatively ground according to process requirements due to surface contact, and the rotating shuttle is strictly prevented from being decomposed and then ground residues are cleaned; in addition, the cleaning liquid is generally a water agent and fire oil which are prepared chemically, the whole cleaning process has high labor intensity and low efficiency, and the cleaning liquid is not environment-friendly.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention provides an environment-friendly semi-automatic rotating and washing machine with rotating shuttle.

In order to solve the technical problem, the technical scheme of the utility model is that:

an environment-friendly semi-automatic rotating and washing machine for a rotating shuttle comprises a main body bracket and an oil pool arranged at the upper part of the main body bracket; a rotating shaft is arranged in the oil pool; a driving mechanism for driving the rotating shaft to rotate is arranged in the main body bracket; the rotating shaft is provided with at least one supporting arm; one end of the support arm, which is far away from the rotating shaft, is provided with a clamping mechanism for mounting the rotating shuttle;

the clamping mechanism comprises a core rod which is arranged on the support arm and used for inserting an outer shuttle of the rotating shuttle into the core rod, and a support column which is used for inserting an inner shuttle of the rotating shuttle into the support arm; the support is provided with a gear; the upper wall of the oil pool is fixedly connected with a gear ring section which is coaxial with the rotating shaft, wherein the gear is meshed with the gear ring section;

wherein the inside of the core rod is provided with an oil outlet channel; the rotary washing machine further comprises an oil supply mechanism for supplying oil to the oil outlet channel.

Furthermore, a positioning block is fixedly mounted on the upper wall of one end, far away from the rotating shaft, of the support arm, wherein the positioning block is located on one side of the core rod.

Furthermore, a limiting block used for being clamped into an inner shuttle notch of the rotating shuttle is arranged on the peripheral wall of the supporting column.

Further, the oil supply mechanism comprises an oil tank, an oil pump and an oil return pipe;

the tank bottom of the oil tank is fixedly provided with a fixed sleeve which is coaxial with the rotating shaft; the rotating shaft is rotatably connected in the fixed sleeve; the upper wall of the fixed sleeve is rotatably connected with a rotating sleeve which is coaxial with the rotating shaft, and the rotating sleeve is fixedly connected to the rotating shaft;

an annular oil cavity which is arranged along the circumferential direction of the rotating sleeve is formed in the bottom wall of the rotating sleeve; a plurality of oil outlets are formed in the peripheral wall of the rotating sleeve; the support arm is provided with an oil inlet communicated with an oil outlet channel of the core rod; the oil outlet is connected with the oil inlet through a connecting pipe;

an oil filling port with one end communicated with the oil cavity is formed in the fixed sleeve;

the oil inlet end of the oil pump is communicated with the oil tank, and the oil outlet end of the oil pump is communicated with the oil filling port;

one end of the oil return pipe is communicated with the oil tank, and the other end of the oil return pipe is communicated with the oil pool.

Further, an annular boss which is coaxial with the rotating shaft is fixedly connected to the inner bottom wall of the oil pool; and a roller positioned on the upper wall of the annular boss is arranged on the lower wall of one end of the support arm, which is far away from the rotating shaft.

Furthermore, a convex section which is convex upwards along the circumferential direction of the annular boss is arranged on the upper wall of the annular boss; one end of the support arm, which is far away from the core rod, is hinged on the rotating shaft; wherein one end of the oil return pipe connected with the oil pool is flush with the upper wall of the convex section.

Further, a plurality of first motors distributed along the circumferential direction of the oil pool are fixedly arranged on the upper wall of the oil pool; wherein the main shaft of the first motor extends into the oil pool and is fixedly connected with a round brush for scrubbing the rotating shuttle.

Furthermore, the driving mechanism comprises a second motor arranged in the main body bracket and a speed reducer connected with the second motor; the output shaft of the speed reducer is fixedly connected with a driving wheel; the lower end of the rotating shaft is fixedly connected with a driven wheel; a belt is sleeved between the driving wheel and the driven wheel.

Compare prior art, the utility model has the advantages that:

the utility model arranges the core rod for installing the outer shuttle of the rotating shuttle and the support column for installing the inner shuttle of the rotating shuttle, and arranges the oil outlet channel in the core rod; therefore, oil can enter the interior of the rotating shuttle through the oil outlet channel to clean the interior of the rotating shuttle;

and set up the gear on the pillar, set up in the oil bath rather than the ring gear section of meshing, so along with the rotation of support arm, the pillar also can rotate thereupon, and then drive the rotating shuttle inner shuttle together of installing rather than rotatory, so the inner shuttle and the outer shuttle of rotating shuttle just can carry out relative rotation, so fluid alright better wash rotating shuttle inside.

To sum up, the utility model discloses, adopt the traditional manual mode of wasing of the mechanical tape body, not only reduced intensity of labour, still improved work efficiency, the cleaning performance also improves greatly simultaneously.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the internal structure of the oil sump according to the present invention;

FIG. 3 is a schematic view of the internal structure of the main body frame;

FIG. 4 is a front view with the body bracket removed;

FIG. 5 is a schematic structural view of the arm;

FIG. 6 is a cross-sectional view of the fixture;

FIG. 7 is a cross-sectional view at the spindle;

fig. 8 is a schematic diagram of the oil feed to the rotary shuttle.

Reference numerals: a. a rotating shuttle; a1, inner shuttle; a2, outer shuttle; a3, moon circle; a4, oil passage; 1. a main body support; 2. an oil sump; 21. an annular boss; 211. a convex section; 3. a rotating shaft; 4. a drive mechanism; 41. a second motor; 42. a speed reducer; 43. a driving wheel; 44. a driven wheel; 45. a belt; 5. a support arm; 51. an oil inlet; 52. a roller; 6. a clamping mechanism; 61. a core rod; 611. an oil outlet channel; 62. positioning blocks; 63. a pillar; 631. a limiting block; 64. a gear; 7. a tooth ring segment; 8. an oil supply mechanism; 81. an oil tank; 82. an oil pump; 83. an oil return pipe; 84. fixing a sleeve; 841. an oil filling port; 85. rotating the sleeve; 851. an oil chamber; 852. an oil outlet; 86. a connecting pipe; 9. a first motor; 91. and (4) round brushing.

Detailed Description

The following detailed description of the embodiments of the present invention is made with reference to the accompanying drawings, so that the technical solution of the present invention can be more easily understood and grasped.

Example (b):

before the present embodiment is described in detail, the rotating shuttle will be briefly described below for a clearer understanding of the present apparatus.

As shown in fig. 8, the conventional rotary hook a is mainly composed of an outer hook a2, an inner hook a1, and a lunar ring a 3; oil passage components, namely an inner shuttle a1 and an outer shuttle a2 can rotate relatively, and the rotating shuttle is internally provided with an oil passage a 4. The present embodiment is explained below:

referring to fig. 1, the embodiment provides an environment-friendly semi-automatic rotating and washing machine with a rotating shuttle a, which comprises a main body bracket 1 and an oil pool 2 arranged at the upper part of the main body bracket 1; the oil pool 2 is mainly used for containing oil for cleaning the rotating shuttle a; during cleaning, the rotating shuttle a is soaked in the oil liquid in the oil pool 2. An opening is formed in the upper part of the oil sump 2, and the rotary hook a is attached and detached through the opening.

Referring to fig. 3, a rotating shaft 3 is arranged in the oil pool 2; the rotating shaft 3 is provided with at least one support arm 5; since 1 arm 5 can carry 1 rotating hook a for cleaning, it is preferable to provide a plurality of arms 5, so that a plurality of rotating hooks a can be cleaned at the same time.

Referring to fig. 2 and 3, an annular boss 21 coaxial with the rotating shaft 3 is fixedly connected to the inner bottom wall of the oil pool 2; one end of the support arm 5, which is far away from the core rod 61, is hinged on the rotating shaft 3, the top of the specific rotating shaft 3 forms a turntable, and one end of the support arm 5 is hinged on the turntable.

As shown in fig. 5, a roller 52 seated on the upper wall of the annular boss 21 is disposed on the lower wall of the end of the support arm 5 away from the rotating shaft 3, the support arm 5 can be turned over up and down, and the roller 52 can roll on the upper wall of the annular boss 21 along the circumferential direction of the annular boss 21. The presence of the annular boss 21 may provide support for the free end of the arm 5.

One end of the support arm 5, which is far away from the rotating shaft 3, is provided with a clamping mechanism 6 for mounting the rotating shuttle a; specifically, the method comprises the following steps:

as shown in fig. 5 and 6, the clamping mechanism 6 includes a core rod 61 provided on the arm 5 for inserting the outer hook a2 of the hook a, and a pillar 63 for inserting into the inner hook a1 of the hook a.

It should be noted that the size of the core rod 61 is adapted to the aperture of the outer shuttle a2, so as to ensure that the outer shuttle a2 of the rotating shuttle a can be inserted on the core rod 61; in this embodiment, a positioning block 62 is fixedly mounted on an upper wall of the end of the arm 5 away from the rotating shaft 3, wherein the positioning block 62 is located on one side of the core rod 61.

The positioning block 62 is mainly configured to abut against a tangent plane of the outer shuttle a2 (a tangent plane is formed on a sidewall of the outer shuttle a2 of the conventional rotating shuttle a), and during installation, the outer shuttle a2 is inserted into the core rod 61, and the tangent plane of the outer shuttle a2 abuts against a side surface of the positioning block 62, so that the outer shuttle a2 cannot rotate relative to the core rod 61 under the limit of the positioning block 62.

A gear 64 coaxially arranged with the strut 63 is fixedly connected to the strut; the upper wall of the oil pool 2 is fixedly connected with a toothed ring section 7 which is coaxial with the rotating shaft 3, the toothed ring section 7 is a broken toothed ring, and the toothed ring is not closed and complete.

Wherein the gear wheel 64 meshes with the toothed ring segment 7; the peripheral wall of the support 63 is provided with a stop block 631 which is used for being clamped into a notch of an inner shuttle a1 of the rotating shuttle a (the upper part of the inner wall of the existing inner shuttle a1 is provided with a notch), so that when the stop block 631 is clamped into the notch, the support 63 and the inner shuttle a1 cannot rotate relatively.

With the above arrangement, when the outer shuttle a2 is inserted into the core rod 61 and the support 63 is inserted into the inner shuttle a1, when the arm 5 rotates along with the rotating shaft 3, the support 63 rotates because the gear 64 is engaged with the toothed ring segment 7, and the inner shuttle a1 rotates relative to the outer shuttle a 2.

In order to flush the inside of the rotary hook a, in the present embodiment, as shown in fig. 6, the inside of the core rod 61 has an oil outlet passage 611; the spin washer further includes an oil supply mechanism 8 for supplying oil into the oil outlet passage 611. The oil supply mechanism 8 supplies oil into the oil outlet channel 611, and the oil is finally ejected from the oil outlet channel 611 and enters the inside of the rotary shuttle a to clean the inside of the rotary shuttle a, and at the same time, the outer shuttle a2 and the inner shuttle a1 rotate relatively, so that the oil entering the rotary shuttle a can sufficiently clean the inside of the rotary shuttle a.

In the present embodiment, as shown in fig. 1, the oil supply mechanism 8 includes an oil tank 81, an oil pump 82, and an oil return pipe 83; the oil tank 81 is mainly used for storing oil, and the oil pump 82 is used for pumping the oil in the oil tank 81.

Specifically, the method comprises the following steps: referring to fig. 7, a fixing sleeve 84 coaxially arranged with the rotating shaft 3 is fixedly installed at the bottom of the oil pool 2; the rotating shaft 3 is rotatably connected in the fixing sleeve 84 to ensure that the rotating shaft 3 can rotate in the fixing sleeve 84.

The upper wall of the fixed sleeve 84 is rotatably connected with a rotating sleeve 85 which is coaxial with the rotating shaft 3, the rotating sleeve 85 is fixedly connected on the rotating shaft 3, wherein the rotating sleeve 85 and the rotating shaft 3 can be of an integrated structure, and the connecting surface of the rotating sleeve 85 and the fixed sleeve 84 is sealed.

An annular oil cavity 851 which is arranged along the circumferential direction of the rotating sleeve 85 is formed in the bottom wall of the rotating sleeve 85; a plurality of oil outlets 852 are formed in the peripheral wall of the rotating sleeve 85, the oil outlets 852 are communicated with the oil chambers 851, and the number of the oil outlets 852 is the same as that of the support arms 5.

As shown in fig. 6, an oil inlet 51 communicated with the oil outlet channel 611 of the core rod 61 is formed at the end of the support arm 5; the oil outlet 852 is connected with the oil inlet 51 through a connecting pipe 86; an oil filling opening 841 is formed in the fixed sleeve 84, and one end of the oil filling opening 841 is communicated with the oil cavity 851.

The oil inlet end of the oil pump 82 is communicated with the oil tank 81 to pump oil in the oil tank 81; the oil outlet end of the oil pump 82 is communicated with the oil filling opening 841, and the oil filling opening 841 can be connected through a pipeline.

With the arrangement, the oil pump 82 pumps the oil in the oil tank 81, enters the oil chamber 851 of the rotating sleeve 85 through the oil filling port 841 on the fixed sleeve 84, then enters the connecting pipe 86 through the oil outlet 852 of the rotating sleeve 85, enters the oil inlet 51 of the support arm 5 through the connecting pipe 86, and finally is sprayed into the interior of the rotating shuttle a through the oil outlet channel 611 of the mandrel 61, so as to clean the interior of the rotating shuttle a.

The purpose of the rotating sleeve 85 is to ensure that the rotating shaft 3 can drive the rotating sleeve 85 to rotate together when rotating, so that the connecting pipe 86 on the rotating sleeve 85 can rotate together with the support arm 5.

One end of the oil return pipe 83 is communicated with the oil tank 81, and the other end of the oil return pipe is communicated with the oil pool 2; as shown in fig. 3, the upper wall of the annular boss 21 is provided with a convex section 211 which protrudes upwards along the circumferential direction of the annular boss 21. It should be noted that the break of the toothed ring segment 7 is located at the position of the raised segment 211, so that the loading/unloading of the rotary hook a can be performed there.

The end of the oil return pipe 83 connected to the oil pool 2 is flush with the upper wall of the protruding section 211, so as to ensure that the liquid level in the oil pool 2 is maintained at a level flush with the upper wall of the protruding section 211.

Because one end of the support arm 5 is hinged on the rotating shaft 3, the support arm 5 can be turned up and down, when the support arm 5 moves to the convex section 211 along with the rotating shaft 3, the movable end of the support arm 5 (i.e. the end close to the core rod 61) can be lifted upwards, and the movable end of the support arm 5 is higher than the liquid level in the oil pool 2 and can not be immersed in the oil pool 2, so that the operation of loading/unloading the rotating shuttle a to the movable end of the support arm 5 can be carried out.

In order to better clean the outer side of the rotating shuttle a, in this embodiment, as shown in fig. 2, a plurality of first motors 9 distributed along the circumferential direction of the oil pool 2 are fixedly mounted on the upper wall of the oil pool 2; wherein the main shaft of the first motor 9 extends into the oil pool 2 and is fixedly connected with a round brush 91 for scrubbing the rotating shuttle a, the round brush 91 is horizontally arranged, and the bristles of the round brush 91 are abutted against the side wall of the rotating shuttle a; therefore, when the support arm 5 drives the rotating shuttle a to move, the circular brush 91 is driven by the first motor 9 to rotate, so that the outer wall of the rotating shuttle a can be scrubbed, and the cleaning effect is improved.

In the present embodiment, as shown in fig. 3 and 4, the driving mechanism 4 includes a second motor 41 installed in the main body frame 1, and a speed reducer 42 connected to the second motor 41; the speed reducer 42 mainly plays a role of speed reduction, and is not described herein since it is a mature prior art.

A driving wheel 43 is fixedly connected to an output shaft of the speed reducer 42; a driven wheel 44 is fixedly connected to the lower end of the rotating shaft 3; a belt 45 is sleeved between the driving wheel 43 and the driven wheel 44. The speed reducer 42 drives the driving wheel 43 to rotate, and then drives the driven wheel 44 to rotate through the belt 45, and finally drives the rotating shaft 3 to rotate, so as to achieve the purpose of driving the support arm 5 to rotate.

The implementation principle is as follows:

in use, the rotary hook a is loaded (at the raised section 211), the support column 63 is removed, the lower end of the support column 63 is inserted into the inner hook a1 of the rotary hook a (ensuring that the stop block 631 on the support column 63 is clamped into the notch of the inner hook a 1), and then the support column 63 together with the rotary hook a is loaded on the mandrel 61, specifically, the outer hook a2 of the rotary hook a is inserted on the mandrel 61 in alignment with the mandrel 61, and the tangent plane of the outer hook a2 abuts against the side wall of the positioning block 62. Cleaning can be started after the rotating shuttle a is loaded.

During cleaning, because the oil tank 2 is filled with oil (the liquid level of the oil is approximately at the position of the convex section 211), the rotating shuttle a is immersed in the oil tank 2 (the rotating shuttle a except the position of the convex section 211) for cleaning, when the support arm 5 rotates along with the rotating shaft 3, under the action of the gear 64 and the toothed ring section 7, the inner shuttle a1 and the outer shuttle a2 of the rotating shuttle a rotate relatively, and meanwhile, the oil pump 82 pumps the oil in the oil tank 81 into the oil outlet channel 611 of the mandrel 61, and then the oil enters the rotating shuttle a from the oil outlet channel 611 to clean the interior of the rotating shuttle a.

And the first motor 9 drives the circular brush 91 to rotate so as to scrub the outer wall of the rotary hook a.

When the support arm 5 drives the rotating shuttle a to move to the convex section 211, the end of the support arm 5 where the rotating shuttle a is installed is lifted above the liquid level in the oil pool 2, and at this time, the rotating shuttle a on the support arm 5 can be taken down and replaced by a new rotating shuttle a for cleaning.

Above only the typical example of the utility model discloses, in addition, the utility model discloses can also have other multiple concrete implementation manners, all adopt the technical scheme that equivalent replacement or equivalent transform formed, all fall in the utility model discloses the scope of claiming.

Claims (8)

1. The utility model provides a semi-automatic machine that changes and washes of rotating shuttle environment-friendly which characterized in that: comprises a main body bracket and an oil pool arranged at the upper part of the main body bracket; a rotating shaft is arranged in the oil pool, and a driving mechanism for driving the rotating shaft to rotate is arranged in the main body bracket; the rotating shaft is provided with at least one supporting arm; one end of the support arm, which is far away from the rotating shaft, is provided with a clamping mechanism for mounting the rotating shuttle;

the clamping mechanism comprises a core rod which is arranged on the support arm and used for inserting an outer shuttle of the rotating shuttle into the core rod, and a support column which is used for inserting an inner shuttle of the rotating shuttle into the support arm; the support is provided with a gear; the upper wall of the oil pool is fixedly connected with a gear ring section which is coaxial with the rotating shaft, wherein the gear is meshed with the gear ring section;

wherein the inside of the core rod is provided with an oil outlet channel; the rotary washing machine further comprises an oil supply mechanism for supplying oil to the oil outlet channel.

2. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 1, is characterized in that: and a positioning block is fixedly arranged on the upper wall of one end of the support arm, which is far away from the rotating shaft, wherein the positioning block is positioned on one side of the core rod.

3. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 1, is characterized in that: and a limiting block which is used for being clamped into the inner shuttle notch of the rotating shuttle is arranged on the peripheral wall of the supporting column.

4. The environment-friendly semi-automatic rotating washing machine with rotating shuttles as claimed in any one of claims 1 to 3, wherein: the oil supply mechanism comprises an oil tank, an oil pump and an oil return pipe;

the tank bottom of the oil tank is fixedly provided with a fixed sleeve which is coaxial with the rotating shaft; the rotating shaft is rotatably connected in the fixed sleeve; the upper wall of the fixed sleeve is rotatably connected with a rotating sleeve which is coaxial with the rotating shaft, and the rotating sleeve is fixedly connected to the rotating shaft;

an annular oil cavity which is arranged along the circumferential direction of the rotating sleeve is formed in the bottom wall of the rotating sleeve; a plurality of oil outlets communicated with the oil cavity are formed in the peripheral wall of the rotating sleeve; the support arm is provided with an oil inlet communicated with an oil outlet channel of the core rod; the oil outlet is connected with the oil inlet through a connecting pipe;

an oil filling port with one end communicated with the oil cavity is formed in the fixed sleeve;

the oil inlet end of the oil pump is communicated with the oil tank, and the oil outlet end of the oil pump is communicated with the oil filling port;

one end of the oil return pipe is communicated with the oil tank, and the other end of the oil return pipe is communicated with the oil pool.

5. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 4, wherein: an annular boss which is coaxial with the rotating shaft is fixedly connected to the inner bottom wall of the oil pool; and a roller positioned on the upper wall of the annular boss is arranged on the lower wall of one end of the support arm, which is far away from the rotating shaft.

6. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 5, wherein: the upper wall of the annular boss is provided with a convex section which is convex upwards along the circumferential direction of the annular boss; one end of the support arm, which is far away from the core rod, is hinged on the rotating shaft; wherein one end of the oil return pipe connected with the oil pool is flush with the upper wall of the convex section.

7. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 1, is characterized in that: a plurality of first motors distributed along the circumferential direction of the oil pool are fixedly arranged on the upper wall of the oil pool; wherein the main shaft of the first motor extends into the oil pool and is fixedly connected with a round brush for scrubbing the rotating shuttle.

8. The environment-friendly semi-automatic rotating washing machine with the rotating shuttle as claimed in claim 1, is characterized in that: the driving mechanism comprises a second motor arranged in the main body bracket and a speed reducer connected with the second motor; the output shaft of the speed reducer is fixedly connected with a driving wheel; the lower end of the rotating shaft is fixedly connected with a driven wheel; a belt is sleeved between the driving wheel and the driven wheel.

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