CN217272642U - Fluid rotary distribution structure and rotary processing equipment - Google Patents

Abstract

The utility model relates to a machining field specifically discloses a rotatory distribution structure of fluid and rotation type processing equipment. The fluid rotating distribution structure comprises an intermediate shaft and a sleeve part, wherein the sleeve part is sleeved on the intermediate shaft and limited to be in rotating movable connection with the intermediate shaft; a sealing ring is arranged between the intermediate shaft and the outer sleeve member; an axial conveying channel is arranged in the intermediate shaft, and at least one radial conveying channel is arranged on the outer sleeve part; at least one distribution groove is formed between the outer sleeve part and the intermediate shaft; the radial conveying channel and the axial conveying channel respectively correspond to the distribution grooves; at least one of the distribution grooves is provided in the form of an open loop. The fluid rotary distribution structure can not only realize the stable supply of fluid between the rotary connection structures on the premise of ensuring the rotary motion; and the on-off control of the fluid can be realized by reasonably adjusting the form of the distribution groove.

Description

Fluid rotary distribution structure and rotary processing equipment

Technical Field

The utility model relates to a machining field especially relates to a rotatory distribution structure of fluid and rotation type processing equipment.

Background

The rotary connection is a common connection in the mechanical field and usually includes a rotary member and a fixed member, which can function as mutual support, for example, in the form of an intermediate shaft and an outer sleeve member. In the rotary joint structure, there are often cases where stable fluid supply between the rotary member and the stationary member is required, such as gas, hydraulic oil, cooling liquid, etc., to the rotary member, but the arrangement of the fluid supply passage has great difficulty in view of the relative movement between the stationary member and the rotary member in the rotary joint structure, and particularly, due to the flow characteristics of the fluid, the problem of fluid leakage needs to be carefully considered.

The application publication number is CN 108953679A's chinese utility model patent application discloses a rotatory oil circuit distributor, including casing, joint body and joint spindle, seted up a plurality of oil inlets on the joint body, be equipped with the axial blind hole on the casing, the joint spindle insert in the blind hole and with blind hole normal running fit, be equipped with the oil-out on the casing, be equipped with seal chamber between blind hole and the joint spindle, oil inlet and oil-out all communicate with seal chamber.

Through the rotary oil way distributor, stable oil supply can be realized between the fixed part and the rotary part in the rotary connecting structure, and oil way sealing and rotary motion are reasonably balanced. However, the rotary distribution structure only realizes stable fluid delivery, does not have a function of controlling the on-off or flow rate of the fluid, and can control the on-off or flow rate of the fluid only by matching with external control equipment such as a valve, and the like, so that the overall structure of the system is relatively complex in operation, and delay and errors are easily generated by matching between the external control equipment and the rotary oil way distributor, thereby affecting the use effect.

Disclosure of Invention

The technical problem to be solved by the utility model is to provide a fluid rotary distribution structure and rotary processing equipment, which can not only realize the stable supply of fluid between rotary connection structures on the premise of ensuring the rotary motion; and the on-off control of the fluid can be realized by reasonably adjusting the form of the distribution groove.

In order to solve the technical problem, the utility model provides a technical scheme as follows: a fluid rotation distribution structure comprises an intermediate shaft and a sleeve member, wherein the sleeve member is sleeved on the intermediate shaft and limited to be in rotary movable connection with the intermediate shaft; a sealing ring is arranged between the intermediate shaft and the outer sleeve piece;

an axial conveying channel is arranged in the intermediate shaft, and at least one radial conveying channel is arranged on the outer sleeve piece;

at least one distribution groove is arranged between the outer sleeve piece and the intermediate shaft, and the distribution groove is annularly arranged around the axis of the intermediate shaft; the radial conveying channel and the axial conveying channel respectively correspond to the distribution grooves;

at least one of the distribution grooves is provided in the form of an open loop.

The cover area of the distribution groove in the circumferential direction is a slotted subsection, the open-loop area of the distribution groove in the circumferential direction is a disconnected subsection, and when the outer sleeve part rotates to the slotted subsection relative to the intermediate shaft and simultaneously communicates the radial conveying channel and the axial conveying channel, the conveying channel of the fluid is smooth; when the outer sleeve part is rotated relative to the intermediate shaft until the radial feed channels or the axial feed regions are aligned with the break-away sections, the feed channels for the fluid are broken.

By adopting the fluid rotary distribution structure, fluid can be stably supplied between the rotary connection structures on the premise of ensuring the relative rotary motion between the outer sleeve part and the intermediate shaft; and the distribution state of the break-off subsection and the slotting subsection of the distribution groove can be reasonably adjusted to realize the control of the on-off of the fluid. Meanwhile, the on-off control of the fluid is controlled by the distribution state of the split groove segments and the split segments in the distribution groove, and the change of the on-off state is automatically carried out simultaneously along with the relative rotation of the outer sleeve piece and the intermediate shaft, so that the matching error and delay between an external control part and a rotary connection structure are avoided, and the accuracy and timeliness of control response are ensured.

Preferably, the distribution grooves are distributed in a dot shape, a linear shape, or a combination of dot and linear shapes in the circumferential direction.

The fluid supply requirements of different working conditions can be met by reasonably arranging the arrangement form of the distribution groove, namely the circumferential coverage area of the slotted sections and the coverage angle of a single slotted section.

Preferably, the number of said radial conveying channels is at least two.

A plurality of radial conveying channels can be arranged to correspond to one station, and the working state of the station can be more diversified through the matching of the plurality of radial conveying channels in a single station. A plurality of stations can also be arranged, each station corresponds to one or more radial conveying channels, and the plurality of stations work alternately or simultaneously to improve the working efficiency.

Preferably, at least one of the distribution grooves is divided circumferentially into at least two slotted segments which are discontinuous with respect to one another.

Each grooved section can be independently communicated with different types or performance parameters of fluid, and a plurality of grooved sections can be communicated with the same fluid.

Preferably, the number of the distribution grooves is at least two, and the distribution grooves are distributed in sequence along the axial direction of the intermediate shaft.

Each distribution groove can be independently communicated with different types or performance parameters of fluids, and a plurality of distribution grooves can be communicated with the same fluid.

Preferably, a sealing ring is arranged between every two adjacent distribution grooves.

The sealing ring can prevent fluid leakage, prevent fluid mixing mutual interference between different distribution grooves and ensure the independence of fluid in each distribution groove.

A rotary processing apparatus comprising a fluid rotary distribution structure as described above; the device also comprises a fluid source and a processing module, wherein one of the fluid source and the processing module is communicated with the radial conveying channel, and the other one of the fluid source and the processing module is communicated with the axial conveying channel.

The fluid source provides high-pressure fluid or forms negative pressure, and the fluid is controlled to flow to the processing module or flow from the processing module to the fluid source through the fluid rotary distribution structure, so that the function of controlling the working state of the processing module or supplying the fluid to the processing module is achieved, and the device has the advantages of simple structure and reliability in working.

A fluid pressure based control system employing a fluid rotary distribution structure as described above; one of the radial conveying channel and the axial conveying channel is communicated with a fluid source, and the other one of the radial conveying channel and the axial conveying channel is communicated with the working unit;

and switching the working modes of the working units according to the change of the communication state between the radial conveying channel and the distribution groove.

Compared with the control mode of the existing fluid distribution structure, the control system integrates the control function on the fluid distribution structure, simplifies the system structure, has high integration level, and has the advantages of accurate control and timely response.

Drawings

Fig. 1 is a front cross-sectional view of a first embodiment of a rotary fluid distribution structure of the present invention;

fig. 2 is a side cross-sectional view of a first embodiment of the fluid rotary distribution structure of the present invention;

fig. 3 is a schematic structural view of an intermediate shaft in a fluid rotary distribution structure according to a first embodiment of the present invention;

fig. 4 is a cross-sectional view of an intermediate shaft in a fluid rotary distribution structure according to a first embodiment of the present invention;

FIG. 5 is an enlarged view of a portion of FIG. 1 at A;

fig. 6 is a front sectional view of a second embodiment of the fluid rotary distribution structure of the present invention;

fig. 7 is a cross-sectional view of an intermediate shaft in a fluid rotary distribution structure according to a third embodiment of the present invention;

fig. 8 is an exploded view of a fourth embodiment of the fluid rotating distribution structure of the present invention;

fig. 9 is a schematic structural view of a fluid rotary distribution structure according to a fourth embodiment of the present invention;

fig. 10 is a schematic structural view of an intermediate shaft in a fluid rotary distribution structure according to a fourth embodiment of the present invention;

fig. 11 is a front sectional view of a fourth embodiment of a rotary distribution structure for fluid in accordance with the present invention;

fig. 12 is a schematic structural view of the rotary processing apparatus of the present embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example one

As shown in fig. 1-5, a fluid rotation distribution structure comprises an intermediate shaft 2 and an outer sleeve member 1, wherein the outer sleeve member 1 is sleeved on the intermediate shaft 2 and is limited to be in rotation movable connection with the intermediate shaft 2. An axial conveying channel 21 is arranged in the intermediate shaft 2, and a radial conveying channel 11 is arranged on the outer sleeve member 1.

As shown in fig. 2 to 4, a distribution groove 22 is provided between the outer sleeve member 1 and the intermediate shaft 2, and the distribution groove 22 is annularly arranged around the axis of the intermediate shaft 2. The radial feed channels 11 and the axial feed channels 21 correspond to the distribution grooves 22, respectively. At least one of the distribution chutes 22 is arranged in an open loop, i.e. a single open loop of the distribution chute 22 is provided, or a plurality of distribution chutes 22 are provided, one of which is arranged in an open loop and the other in a closed loop.

As shown in fig. 3 and 4, in particular, the coverage area of the distribution groove 22 in the circumferential direction is a slotted segment 221, and the open-loop area of the distribution groove 22 in the circumferential direction is a broken segment 222. By properly arranging the configuration of the distribution groove 22, i.e. the circumferential coverage area of the distribution groove 22, and the arc of the individual grooved sections 221 of the distribution groove 22, the fluid supply requirements of different conditions can be used.

It should be noted that the distribution grooves may be provided on the intermediate shaft, with the corresponding axial delivery channels directly communicating with the distribution grooves, and with the radial delivery channels axially aligned with the corresponding distribution grooves. The distribution grooves can also be arranged on the outer sleeve part, specifically on the inner side surface of the outer sleeve part, the corresponding radial conveying channels are directly communicated with the distribution grooves, the axial conveying channels are provided with openings on the side surface of the intermediate shaft through the transition channels, and the openings are aligned with the corresponding distribution grooves in the axial direction.

The following description will be made by taking a form in which the distribution grooves are provided on the intermediate shaft as an example.

When the outer sleeve member 1 is rotated relative to the intermediate shaft 2 until the radial conveying channels 11 are aligned with the slotted segments 221, the radial conveying channels 11 are communicated with the distribution grooves 22 and the axial conveying channels 21, i.e. the conveying channels for the fluid are unblocked; when the outer sleeve part 1 is rotated relative to the intermediate shaft 2 until the radial feed channels 11 are aligned with the break-off portions 222, the radial feed channels 11 are misaligned with the distributor grooves 22 and the axial feed channels 21, i.e. the feed channels for the fluid are broken.

By adopting the fluid rotary distribution structure, fluid can be stably supplied between the outer sleeve member 1 and the intermediate shaft 2 of the rotary connection structure on the premise of ensuring the relative rotary motion between the outer sleeve member 1 and the intermediate shaft 2. The distribution states of the open section 221 and the break section 222 in the distribution groove 22 can be reasonably adjusted to realize the control of the on-off of the fluid. Meanwhile, the on-off control of the fluid is controlled by the distribution states of the groove sections 221 and the disconnection sections 222 in the distribution groove 22, and the change of the on-off state is automatically carried out simultaneously along with the relative rotation of the outer sleeve member 1 and the intermediate shaft 2, so that the matching error and delay between an external control component and a rotary connection structure are avoided, and the accuracy and timeliness of control response are ensured.

It should be noted that, the fluid circulating in the fluid rotating distribution structure of the present application may be a liquid, for example: hydraulic oil, cutting fluid, lubricating oil, and the like, and may be gas, for example: high pressure air, nitrogen, noble gases, and the like.

It should be noted that, under specific operating conditions, the intermediate shaft 2 may be fixedly disposed, and the corresponding outer sleeve member 1 rotates relative to the intermediate shaft 2; it is also possible to arrange the outer sleeve part 1 fixedly and the intermediate shaft 2 as a rotating part.

The outer sleeve member 1 and the intermediate shaft 2 are in transition fit or clearance fit, namely the inner side surface of the outer sleeve member 1 is in hard contact with the outer side surface of the intermediate shaft 2, so that the clearance between the outer sleeve member 1 and the intermediate shaft 2 can be effectively controlled, and the fluid leakage rate can be controlled.

As shown in fig. 1 and 5, a seal ring 3 is provided between the intermediate shaft 2 and the outer sleeve member 1 to further improve the sealing effect between the intermediate shaft 2 and the outer sleeve member 1. Specifically, at least two sealing rings 3 are arranged between the intermediate shaft 2 and the outer sleeve member 1, and the distribution groove 22 is located between the two sealing rings 3. When the number of the distribution grooves 22 is at least two, the sealing ring 3 is also arranged between every two adjacent distribution grooves 22.

As shown in fig. 5, in particular, the sealing ring 3 includes an elastic outer layer 31 and a rigid inner layer 32 in the radial direction, and the elastic outer layer 31 and the rigid inner layer 32 are integrally disposed. The inner side of the outer sleeve member 1 is distributed with a sealing groove, the elastic outer layer 31 of the sealing ring 3 is arranged in the sealing groove, and the rigid inner layer 32 of the sealing ring 3 is in sliding contact with the intermediate shaft 2. The inner wall of said rigid inner layer 32 is provided with at least one buffer groove 33 arranged annularly around the axis of the sealing ring 3.

The sealing ring 3 can prevent fluid leakage, prevent fluid mixing interference between different distribution grooves 22 and ensure independence of fluid in each distribution groove 22.

The elastic outer layer 31 is arranged in the sealing ring 3 and deforms through extrusion, reliable sealing between the sealing ring 3 and the outer sleeve member 1 is guaranteed, certain pretightening force is applied to the rigid inner layer 32, the rigid inner layer 32 is in closer contact with the intermediate shaft 2 under the action of the pretightening force, and the sealing effect is improved. The rigid inner layer 32 is in rigid contact with the intermediate shaft 2 and slides relative to the outer lateral surface of the intermediate shaft 2 along with the rotation of the outer sleeve member 1 and the intermediate shaft 2, and simultaneously has the effects of movement support and sealing. Meanwhile, the provision of the buffer groove 33 may further enhance the sealing effect in a labyrinth form.

Example two

Compared with the first embodiment, the difference of the present embodiment is that the number of at least one of the axial conveying channels 21 and the radial conveying channels 11 is greater than or equal to two. By providing a plurality of radial feed channels 11 and axial feed channels 21, a rotary distribution of multiple stations or multiple fluid sources can be achieved.

In particular, a plurality of stations may be provided on the jacket 1, each communicating with a different radial conveying channel 11. Through the relative rotation of the outer sleeve part 1 and the intermediate shaft 2, the radial conveying channels 11 corresponding to all the stations move relative to the distribution grooves 22, the communication state between the distribution grooves 22 and the radial conveying channels 11 is changed along with the change of the communication state, the flow state of the fluid in all the stations is controlled, and the flow state is matched with the processing flow in all the stations.

Taking a specific use condition as an example, as shown in fig. 6, the outer sleeve member 1 is provided with three stations, namely a first processing station, a second processing station and a third processing station, and each station is corresponding to a radial conveying channel 11. However, when the radial conveying channel 11 corresponding to the first processing station is aligned with the disconnecting section 222, the radial conveying channels 11 corresponding to the second processing station and the third processing station are both aligned with the slotting section 221, at this time, the first processing station is in a loading and unloading state, and the second processing station and the third processing station are in a working state.

Similarly, a plurality of stations can be arranged on the intermediate shaft 2, and the corresponding axial conveying channels 21 correspond to the stations one by one.

The embodiment is suitable for a multi-station scene, and a plurality of radial conveying channels 11 or axial conveying channels 21 are arranged to correspond to stations, and the working state of each station is controlled through the distribution groove 22, so that independent work of a plurality of stations can be simultaneously and accurately controlled, and the working efficiency is improved. And through the rotation of outer sleeve spare 1 for jackshaft 2 switch between different stations, the position and the operating condition synchronous switch of each station, the control response is timely, and control effect is reliable, and degree of automation is high.

EXAMPLE III

In contrast to the first embodiment, the present embodiment differs in that the distribution groove 22, in which the ring is arranged open, is arranged circumferentially in at least two slotted segments 221 that are discontinuous from one another, i.e. in that at least two interrupted segments 222 are arranged circumferentially. The number and position of the grooved segments 221 and the angle covered by each grooved segment 221 can be adjusted according to the actual control requirement. The slotted segments 221 are distributed in a dot, linear, or combination of dot and linear form.

In order to further increase the diversity of the control modes, the same distribution chute 22 corresponds to at least two axial conveying channels 21, wherein each axial conveying channel 21 communicates with one of the slotted segments 221 or with a plurality of slotted segments 221 simultaneously. In a specific embodiment, the slotted segments 221 are in one-to-one correspondence with the axial feed channels 21, i.e., each slotted segment 221 can be independently provided with a fluid source. Different fluid sources can adjust the working state on the corresponding station by changing the fluid types and the fluid parameters, thereby further increasing the diversity of the control state.

Taking a specific working condition as an example, as shown in fig. 7, the distribution chute 22 is provided with three slotted sections 221 along the circumferential direction, and three axial conveying channels 21 are provided to correspond to the slotted sections 221 one by one, wherein two axial conveying channels 21 are communicated with a high-pressure fluid source, and the other axial conveying channel 21 is communicated with a negative-pressure source. Correspondingly, the processing mechanism on the station is set to be communicated with a high-pressure fluid source to enter a working state, and communicated with a negative pressure source to release the working state, and when the radial conveying channel 11 is aligned with the disconnecting section 222, the processing mechanism keeps the existing working state.

Example four

The present embodiment is different from the embodiment in that at least two distribution grooves 22 are formed in an open loop. As a specific embodiment, the number of radial conveying channels 11 per station of the casing member 1 is the same as the number of distribution grooves 22.

The diversity of the control system can be further increased by cooperation between different distribution troughs 22. In addition, different distribution troughs 22 may be used to deliver different types of fluids, increasing the applicability of the fluid rotary distribution structure of the present application.

Taking a specific use condition as an example, as shown in fig. 8-11, the number of the distribution grooves 22 is three, wherein one distribution groove 22 is arranged in a closed loop manner, and the other two distribution grooves 22 are arranged in an open loop manner. Correspondingly, three axial conveying channels 21 are provided in one-to-one correspondence with the distribution grooves 22. A distribution channel 22 in the form of a closed loop communicates high pressure fluid for cooling the processing station. One of the distribution grooves 22 arranged in an open loop is communicated with a high-pressure fluid source, the other distribution groove is communicated with a negative pressure source, and the slotted sections 221 between the two distribution grooves 22 are partially or completely staggered.

The processing mechanism on the station is set to enter a first working state when being independently communicated with the high-pressure fluid source, enter a second working state when being independently communicated with the negative pressure source, and release the working state when being communicated with the high-pressure fluid source and the negative pressure source.

EXAMPLE five

As shown in fig. 12, a rotary processing apparatus includes a fluid rotary distribution structure 01 as described in the first to third embodiments; a fluid source (not shown) and a processing module 02 are also included, one of the fluid source and the processing module 02 being in communication with the radial feed channel 11 and the other being in communication with the axial feed channel 21.

The fluid source provides high-pressure fluid or forms negative pressure, and the fluid is controlled to flow to the processing module or from the processing module to the fluid source through the fluid rotary distribution structure, so that the function of controlling the working state of the processing module or supplying the processing module for use is achieved, and the device has the advantages of simple structure and reliable work.

EXAMPLE six

A fluid pressure based control system employing a fluid rotation distribution structure as described in embodiments one-third; one of the radial conveying channel 11 and the axial conveying channel is communicated with a fluid source, and the other one is communicated with the working unit;

the operation mode of the operation unit is switched according to the change of the communication state between the radial direction feed passage 11 and the distribution groove 22.

Compared with the control mode of the existing fluid distribution structure, the control system integrates the control function on the fluid distribution structure, simplifies the system structure, has high integration level, and has the advantages of accurate control and timely response.

In summary, the above description is only a preferred embodiment of the present invention and should not be taken as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention should be included within the scope of the present invention.

Claims (7)

1. A fluid rotation distribution structure comprises an intermediate shaft and an outer sleeve member, wherein the outer sleeve member is sleeved on the intermediate shaft and limited to be in rotary movable connection with the intermediate shaft; a sealing ring is arranged between the intermediate shaft and the outer sleeve member;

an axial conveying channel is arranged in the intermediate shaft, and at least one radial conveying channel is arranged on the outer sleeve part;

at least one distribution groove is formed between the outer sleeve part and the intermediate shaft, and the distribution groove is annularly arranged around the axis of the intermediate shaft; the radial conveying channel and the axial conveying channel respectively correspond to the distribution grooves;

the method is characterized in that:

at least one of the distribution grooves is provided in the form of an open loop.

2. The fluid rotary distribution structure of claim 1, wherein: the distribution grooves are distributed in a form of point, line or combination of point and line in the circumferential direction.

3. The fluid rotary distribution structure of claim 1, wherein: the number of the radial conveying channels is at least two.

4. The fluid rotary distribution structure of claim 1, wherein: at least one of the distribution grooves comprises at least two groove sections which are discontinuous with each other in the circumferential direction.

5. The fluid rotary distribution structure according to any one of claims 1 to 4, wherein: the number of the distribution grooves is at least two.

6. The fluid rotary distribution structure of claim 5, wherein: and a sealing ring is arranged between every two adjacent distribution grooves.

7. A rotary processing apparatus, characterized in that: comprising a fluid rotary distribution structure according to any of claims 1-6; the device also comprises a fluid source and a processing module, wherein one of the fluid source and the processing module is communicated with the radial conveying channel, and the other one of the fluid source and the processing module is communicated with the axial conveying channel.

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