CN212170252U - High-pressure micro-mist nozzle assembly dismounting tool - Google Patents

Abstract

The utility model discloses a high-pressure micro-mist nozzle assembly dismounting tool, which comprises a cylinder body, a clamping mechanism, a shell and a force unloading ring; wherein, the cylinder body is provided with a containing hole, and the side wall of the cylinder body is provided with a first elastic positioning mechanism; the clamping mechanism is arranged in the accommodating hole, a plurality of straight clamping pieces are arranged on the clamping mechanism, and the plurality of straight clamping pieces gather and extend towards the axis of the clamping mechanism; the outer side surfaces of the straight clips are abutted against the inner wall of the shell, and clamping spaces for clamping the nozzles are formed among the inner side surfaces of the straight clips; the force unloading ring is arranged in the accommodating hole, a plurality of positioning holes are uniformly formed in the side wall of the force unloading ring, the positioning holes are matched with the first elastic positioning mechanism, and the force unloading ring is further provided with a mounting hole matched with the nozzle base. The utility model provides a little fog nozzle assembly dismouting frock of high pressure has realized the quick assembly disassembly to the nozzle, has promoted dismouting efficiency, the damage that causes it when also having reduced the dismouting nozzle simultaneously.

Description

High-pressure micro-mist nozzle assembly dismounting tool

Technical Field

The utility model relates to a tobacco machinery technical field especially relates to a little fog nozzle assembly dismouting frock of high pressure.

Background

The cigarette production process requires strict control of the temperature and humidity of the surrounding environment, so that the temperature and humidity can be regulated and controlled by widely adopting a high-pressure micro-fog system and matching with a building automatic control system. The high-pressure micro-mist nozzle is a key component of a high-pressure micro-mist system, and water vapor is atomized by the nozzle and then sprays mist particles, so that the mist particles can quickly absorb heat from air to complete vaporization and diffusion, and the purposes of air humidification and cooling are fulfilled. The nozzle is a vulnerable part, when the nozzle is seriously worn, the problems of poor atomization effect, large pressure loss, easy blockage and the like can occur, even the phenomena of water seepage and water leakage occur, and the aim of humidification and temperature reduction can not be fulfilled; the worn nozzle ring therefore needs to be replaced in a timely manner.

The nozzle assembly is composed of a base, a nozzle and the like, and is easy to damage during disassembly due to tight matching and high precision requirement. At present, after a nozzle assembly breaks down, tools such as a screwdriver and a nipper plier need to be adopted to disassemble a flow guide cover and the nozzle assembly, the disassembly process is complicated and time-consuming, and the nozzle connecting wire is easy to break and scrap due to overload of central stress in the disassembly process, so that resource waste is caused. In addition, because the disassembly and assembly space of the nozzle assembly is small, the nozzle assembly is difficult to clamp, the nozzle assembly is easy to fall off in the disassembly and assembly process, and the nozzle assembly is difficult to take out due to the space limitation after falling.

In view of the above reasons, it is especially important to study a high-pressure micro-mist nozzle assembly dismounting tool.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a little fog nozzle assembly dismouting frock of high pressure improves nozzle assembly dismouting efficiency, reduces the damage that causes among the dismouting process.

The utility model provides a little fog nozzle assembly dismouting frock of high pressure, wherein, include:

the device comprises a barrel body, a first elastic positioning mechanism and a second elastic positioning mechanism, wherein a containing hole is formed in the barrel body, and the side wall of the barrel body is provided with the first elastic positioning mechanism;

the clamping mechanism is arranged in the accommodating hole, a plurality of straight clamping pieces are arranged on the clamping mechanism, the straight clamping pieces are uniformly distributed on the circumferential surface, and the straight clamping pieces are gathered and extend towards the axis of the clamping mechanism;

the shell is arranged in the accommodating hole, the shell is connected with the clamping mechanism, an accommodating space is arranged in the shell, the straight clamping pieces are arranged in the accommodating space, the outer side surfaces of the straight clamping pieces are abutted to the inner wall of the accommodating space, and a clamping space for clamping the nozzle is formed among the inner side surfaces of the straight clamping pieces;

the force unloading ring is arranged in the accommodating hole, a plurality of positioning holes are uniformly formed in the side wall of the force unloading ring, the positioning holes are matched with the first elastic positioning mechanisms, and mounting holes matched with the nozzle base are formed in the force unloading ring.

The high-pressure micro-mist nozzle assembly dismounting tool is preferably provided with an inclined surface or an arc-shaped surface.

The high-pressure micro-mist nozzle assembly dismounting tool comprises a first elastic positioning mechanism, a second elastic positioning mechanism and a third elastic positioning mechanism, wherein the first elastic positioning mechanism comprises a limiting column, a first spring and a first locking bolt;

the side wall of the barrel is provided with a first limiting hole, the limiting column is arranged in the first limiting hole, the limiting end of the limiting column extends out of the first limiting hole and then is matched with the positioning hole, two ends of the first spring are respectively abutted against the limiting column and the first locking bolt, and the first locking bolt is fixedly connected with the first limiting hole.

The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly preferably comprises a first hole and a second hole, the diameter of the first hole is larger than that of the second hole, the force-releasing ring is arranged in the first hole, the clamping mechanism and the shell are arranged in the second hole, and the first limiting hole is communicated with the first hole.

The high-pressure micro-mist nozzle assembly dismounting tool is characterized in that the side wall of the force unloading ring is provided with an arc-shaped groove.

The tool for assembling and disassembling the high-pressure micro-mist nozzle assembly is characterized in that the depth of the first hole is greater than the thickness of the force-unloading ring, and after the positioning hole is matched with the limiting column, a gap is kept between the force-unloading ring and a step surface formed by the first hole and the second hole.

The high-pressure micro-mist nozzle assembly dismounting tool preferably further comprises a bearing, a rotating shaft is further arranged on the clamping mechanism, an inner ring of the bearing is fixedly connected with the rotating shaft, and an outer ring of the bearing is fixedly connected with the second hole.

The high-pressure micro-mist nozzle assembly dismounting tool preferably further comprises a connecting body, the straight clamping piece and the rotating shaft are respectively arranged on two sides of the connecting body, an external thread is arranged on the connecting body, an internal thread is arranged on the inner wall of the shell, and the shell is sleeved on the straight clamping piece and then fixedly connected with the connecting body through the matching of the external thread and the internal thread.

The high-pressure micro-mist nozzle assembly dismounting tool preferably further comprises a driving connecting piece, a driving hole is formed in one end, far away from the containing hole, of the barrel, one end of the driving connecting piece is fixedly connected with the driving hole, and the other end of the driving connecting piece is used for being connected with an electric tool.

The high-pressure micro-mist nozzle assembly dismounting tool preferably further comprises a second spring, a second locking bolt and a ball, wherein a second limiting hole and a third limiting hole are further formed in the side wall of the cylinder body, the second limiting hole, the third limiting hole and the driving hole are sequentially communicated, the diameter of the second limiting hole is larger than that of the third limiting hole, the ball is arranged in the second limiting hole, and part of the ball protrudes from the third limiting hole into the driving hole;

two ends of the second spring are respectively abutted against the ball and the second locking bolt;

the second locking bolt is fixedly connected with the second limiting hole;

the driving connecting piece is provided with an annular groove, and the annular groove is in clamping fit with the ball.

The embodiment of the utility model provides a little fog nozzle assembly dismouting frock of high pressure has realized the quick assembly disassembly to the nozzle, has promoted dismouting efficiency, the damage to it when also having reduced the dismouting nozzle simultaneously and causing.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

FIG. 1 is a schematic structural view of a nozzle assembly;

FIG. 2 is an exploded view of the nozzle assembly;

fig. 3 is an exploded view (one) of the high-pressure micro-mist nozzle assembly dismounting tool provided by the embodiment of the invention;

fig. 4 is an exploded view (ii) of the high-pressure micro-mist nozzle assembly dismounting tool provided by the embodiment of the invention;

fig. 5 is a half sectional view of a high-pressure micro-mist nozzle assembly dismounting tool provided by the embodiment of the utility model;

FIG. 6 is a schematic structural view of a force relief ring;

FIG. 7 is a front view of the force relief ring;

FIG. 8 is a cross-sectional view taken along line A-A of FIG. 7;

FIG. 9 is a schematic view of the clamping mechanism;

FIG. 10 is another schematic view of the clamping mechanism;

fig. 11 is an exploded view (a) of a high-pressure fine-mist nozzle assembly dismounting tool according to another embodiment of the present invention;

fig. 12 is an exploded view of a high-pressure fine mist nozzle assembly dismounting tool according to another embodiment of the present invention;

FIG. 13 is a cross-sectional view of the cartridge;

fig. 14 is a half sectional view of a high-pressure fine spray nozzle assembly dismounting tool according to another embodiment of the present invention;

fig. 15 is a schematic structural view of the locking pin.

Description of reference numerals:

1-nozzle 2-base 3-stud

100-cylinder 110-containing hole 111-first hole

112-second hole 113-gap 120-drive hole

130-first limiting hole 140-second limiting hole 150-first locking hole

151-straight hole portion 152-transverse groove portion 200-clamping mechanism

210-straight clip 211-arc surface 220-connector

221-second locking hole 230-rotating shaft 300-force-removing ring

310-mounting hole 320-positioning hole 321-cylindrical surface

322-conical surface 330-arc groove 400-shell

500-drive connection 510-annular groove 600-bearing

700-first elastic positioning mechanism 710-first locking bolt 720-first spring

730-limit column 800-second elastic positioning mechanism 810-second locking bolt

820-second spring 830-ball 900-locking pin

910-locking segment 920-bending segment

Detailed Description

Various exemplary embodiments of the present disclosure will now be described in detail with reference to the accompanying drawings. The description of the exemplary embodiments is merely illustrative and is in no way intended to limit the disclosure, its application, or uses. The present disclosure may be embodied in many different forms and is not limited to the embodiments described herein. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. It should be noted that: the relative arrangement of parts and steps, the composition of materials, numerical expressions and numerical values set forth in these embodiments are to be construed as merely illustrative, and not as limitative, unless specifically stated otherwise.

As used in this disclosure, "first", "second": and the like, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element preceding the word covers the element listed after the word, and does not exclude the possibility that other elements are also covered. "upper", "lower", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

In the present disclosure, when a specific component is described as being located between a first component and a second component, there may or may not be intervening components between the specific component and the first component or the second component. When it is described that a specific component is connected to other components, the specific component may be directly connected to the other components without having an intervening component, or may be directly connected to the other components without having an intervening component.

All terms (including technical or scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs unless specifically defined otherwise. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

As shown in fig. 1 to 9, an embodiment of the present invention provides a high-pressure micro-mist nozzle assembly dismounting tool, which includes a cylinder 100, a clamping mechanism 200, a housing 400, and a force-releasing ring 300; wherein, the cylinder 100 is provided with a containing hole 110, and the side wall of the cylinder 100 is provided with a first elastic positioning mechanism 700; the clamping mechanism 200 is arranged in the accommodating hole 110, a plurality of straight clamping pieces 210 are arranged on the clamping mechanism 200, the plurality of straight clamping pieces 210 are uniformly distributed on the circumferential surface, and the plurality of straight clamping pieces 210 are gathered and extended towards the axis of the clamping mechanism 200; the shell 400 is arranged in the accommodating hole 110, the shell 400 is connected with the clamping mechanism 200, an accommodating space is arranged in the shell 400, the straight-going clamping pieces 210 are arranged in the accommodating space, the outer side surfaces of the straight-going clamping pieces 210 are abutted against the inner wall of the accommodating space, and a clamping space for clamping the nozzle 1 is formed between the inner side surfaces of the straight-going clamping pieces 210; the force-releasing ring 300 is arranged in the accommodating hole 110, a plurality of positioning holes 320 are uniformly arranged on the side wall of the force-releasing ring 300, the positioning holes 320 are matched with the first elastic positioning mechanism 700, and the force-releasing ring 300 is also provided with a mounting hole 310 used for being matched with the nozzle base 2.

As shown in fig. 1 and 2, the conventional high pressure fine spray nozzle assembly generally includes a base 2 and a nozzle 1, one end of the base 2 is connected to the nozzle 1, and the other end of the base 2 has a stud 3 for connecting to equipment, and the high pressure fine spray nozzle assembly is mounted or dismounted by applying a torque to the base 2. The base 2 is generally a hexagonal cylinder, and in this embodiment, the mounting hole 310 of the force-releasing ring 300 may also be a hexagonal hole that is matched with the hexagonal cylinder in order to be matched with the base 2.

When the nozzle assembly needs to be disassembled, the cylinder body 100 in this embodiment may be connected to the driving mechanism, and the other end of the cylinder body 100 is connected to the base 2 through the mounting hole 310 on the force-releasing ring 300, and at the same time, the nozzle 1 may pass through the mounting hole 310 and then extend into the clamping space formed between the inner side surfaces of the straight clips 210. Wherein, the clamping space is a space with approximate hole shape, the diameter of the clamping space is slightly smaller than the outer diameter of the nozzle 1, when the nozzle 1 is inserted into the clamping space, each of the clips 210 can be pressed, the pressed clips 210 are twisted and inclined at a certain angle, that is, one straight traveling jaw 210 is pressed and twisted close to an adjacent straight traveling jaw 210, meanwhile, part of the straight clips 210 have a tendency of expanding outward in the radial direction after being extruded, but are blocked by the housing 400, and the straight clips 210 are simultaneously extruded by the housing 400 and the nozzle 1 and then elastically deformed, so that the extrusion force of the straight clips 210 on the nozzle 1 is increased, thereby can promote the tight fixity of clamp to nozzle 1, when base 2 takes down from equipment, through the centre gripping of craspedodrome clamping piece 210 to nozzle 1, can make whole high pressure little fog nozzle assembly can not drop from this dismouting frock.

In the disassembling process, the cylinder 100 can be driven to rotate by the driving mechanism, and the cylinder 100 drives the force-releasing ring 300 to synchronously rotate, so that the base 2 can be driven to rotate by the force-releasing ring 300, and the base 2 can be disassembled.

Conversely, when it is desired to install the nozzle assembly on the apparatus, the barrel 100 may be driven in a reverse direction to gradually tighten the stud 3 on the base 2 onto the apparatus. When the base 2 reaches a preset torque value in the installation process, the base 2 cannot continue to rotate, the barrel 100 still rotates under the action of the driving mechanism at the moment, and the force unloading ring 300 also has a tendency of rotating relative to the base 2; because the force-releasing ring 300 is fixedly connected with the base 2 through the mounting hole 310, the force-releasing ring 300 is restrained by the base 2 and can not rotate, at this time, torsion is generated between the rotating cylinder 100 and the stationary force-releasing ring 300, so that the part of the first elastic positioning mechanism 700, which is matched with the positioning hole 320, is moved out of the positioning hole 320 under the action of the torsion, so that the first elastic positioning mechanism 700 slightly retracts, at this time, the cylinder 100 can continuously rotate relative to the force-releasing ring 300, and when the first elastic positioning mechanism 700 reaches the next positioning hole 320, the first elastic positioning mechanism 700 can be matched with the positioning hole 320 again, and at the same time, the first elastic positioning mechanism 700 can impact the edge of the positioning hole 320, and can transmit the striking sense generated by the impact to the operator, and simultaneously generate striking sound, the operator can clearly judge that the base 2 is mounted through the sensing and sound, and stops the operation of the driving mechanism. Of course, since the driving mechanism drives the barrel 100 to rotate at a higher speed, when the operator recognizes that the preset torque is reached, the first elastic positioning mechanism 700 may be engaged with and disengaged from the plurality of positioning holes 320, and may make a sound of multiple impacts, so that the operator may accurately determine that the base 2 has reached the preset torque. In addition, through the cooperation of the first elastic positioning mechanism 700 and the force unloading ring 300, the torsion from the cylinder body 100 is released when the preset torque is reached, and the phenomenon that the driving mechanism is locked due to the clamping between the force unloading ring 300 and the cylinder body 100 when the preset torque is reached can be avoided.

As shown in fig. 9, the straight clips 210 are provided with an inclined surface or an arc surface 211 to provide guidance for the insertion of the nozzle 1, so that the nozzle 1 can be conveniently inserted into the clamping space formed by each straight clip 210, and the nozzle 1 can gradually press the straight clips 210 during the insertion process, so that the straight clips are elastically deformed to clamp the nozzle 1.

Further, in order to improve the clamping force of the straight clips 210 on the nozzle 1, the straight clips 210 are provided with wear-resistant coating glue.

In the embodiment, in order to realize that the rectilinear clip 210 has certain elasticity, so as to clamp the nozzle 1 through elastic deformation of the rectilinear clip 210, and simultaneously ensure that the rectilinear clip 210 has certain strength, and cannot be worn and broken after long-term use, the rectilinear clip 210 is preferably a copper sheet.

Specifically, the first elastic positioning mechanism 700 includes a spacing post 730, a first spring 720 and a first locking bolt 710; the side wall of the barrel 100 is provided with a first limiting hole 130, the limiting column 730 is arranged in the first limiting hole 130, the limiting end of the limiting column 730 extends out of the first limiting hole 130 and then is matched with the positioning hole 320 on the force-removing ring 300, two ends of the first spring 720 are respectively abutted against the limiting column 730 and the first locking bolt 710, and the first locking bolt 710 is fixedly connected with the first limiting hole 130.

After the positioning hole 320 of the force-releasing ring 300 is aligned with the limiting post 730, the limiting end of the limiting post 730 can be pressed against the positioning hole 320 by the elastic force of the spring, so that the force-releasing ring 300 is positioned in the cylinder 100, and the force-releasing ring 300 can rotate along with the cylinder 100.

When the nozzle assembly is installed on the apparatus, when the nozzle assembly is tightened to a predetermined torque, the force-releasing ring 300 is restrained by the nozzle base 2 and does not rotate any more, at this time, as the barrel 100 continues to rotate, a torsion force is generated between the barrel 100 and the force-releasing ring 300, the torsion force acts on the position-limiting post 730, and the torsion force generates a component force in the axial direction of the position-limiting post 730 to push the position-limiting post 730 to disengage from the position-limiting hole 320, and after the position-limiting post 730 is completely disengaged from the position-limiting hole 320, the position-limiting post 730 keeps contact with the side wall of the force-releasing ring 300 except the position-limiting hole 320 under the action of the spring, and as the barrel 100 rotates, the position-limiting end of the position-limiting post 730 slides on the side wall of the force-releasing ring 300, until the position-limiting post 730 reaches the next position-limiting hole 320, the position-limiting end of the position-limiting post 730 can be re-matched with the current position, the vibration touch feeling and the collision sound are brought to an operator, so that the operator is reminded that the nozzle assembly is installed; meanwhile, the matching mode of the limiting column 730 and the positioning hole 320 can realize automatic force unloading when the preset torque is reached, and the clamping stagnation problem is avoided.

The first limiting hole 130 is a tapered hole, the limiting column 730 is a tapered column matched with the tapered hole, and the end surface of the limiting column 730 is a spherical surface.

The tapered shape of the limiting post 730 means that the diameter of the limiting post 730 is gradually reduced toward the direction of the limiting end, and when the limiting post 730 is engaged with the first limiting hole 130, the limiting post 730 can be prevented from automatically falling off from the first limiting hole 130; by setting the end surface of the position-limiting post 730 to be a spherical surface, when a torque force is generated between the force-releasing ring 300 and the barrel 100, a component force for pushing the position-limiting post 730 is generated after the inner wall of the positioning hole 320 contacts the spherical surface, so as to avoid the clamping stagnation between the positioning hole 320 and the position-limiting post 730.

Further, as shown in fig. 8, the positioning hole 320 includes a conical surface 322 and a cylindrical surface 321, the conical surface 322 and the cylindrical surface 321 are two opposite surfaces in the positioning hole 320, and the conical surface 322 and the cylindrical surface 321 are both disposed in the rotation direction of the force-removing ring 300, where the conical surface 322 refers to an acute angle between an inner surface of the positioning hole 320 and the axial direction, and the cylindrical surface 321 refers to an inner surface of the positioning hole 320 parallel to the axial direction.

When the nozzle 1 needs to be disassembled, the barrel 100 drives the force-releasing ring 300 to rotate through the limiting column 730, and at the moment, the limiting column 730 is always attached to the cylindrical surface 321 in the positioning hole 320, so that a tangential force which can drive the force-releasing ring 300 to rotate is generated on the side wall of the positioning hole 320, a component force in the radial direction of the force-releasing ring 300 cannot be generated, the force-releasing ring 300 can be ensured to rotate reliably, and the nozzle 1 can be disassembled.

When the nozzle 1 needs to be installed, the barrel 100 drives the force-discharging ring 300 to rotate through the limiting column 730, at the moment, the spherical surface of the limiting column 730 is always in contact with the conical surface 322 in the positioning hole 320, at the moment, the spherical surface of the limiting column 730 can generate a tangential force for driving the force-discharging ring 300 to rotate on the conical surface 322, and meanwhile, a radial force for pushing the limiting column 730 to be far away from the force-discharging ring 300 can be generated, when the base 2 of the nozzle 1 does not reach a preset torque, the tangential force can always drive the force-discharging ring 300 to rotate, and the limiting column 730 cannot be pushed out of the positioning hole 320 by the radial force; when the base 2 of the nozzle 1 reaches the preset torque, the force-releasing ring 300 does not rotate, and the radial force can push out the limit column 730 to release the force.

Further, the accommodation hole 110 includes a first hole 111 and a second hole 112, the diameter of the first hole 111 is larger than the diameter of the second hole 112, the force-releasing ring 300 is disposed in the first hole 111, the clamping mechanism 200 and the housing 400 are disposed in the second hole 112, and the first stopper hole 130 communicates with the first hole 111.

As shown in fig. 6 and 7, the side wall of the force-releasing ring 300 is provided with an arc-shaped groove 330, the arc-shaped groove 330 surrounds the side wall of the force-releasing ring 300, and the limiting end of the limiting post 730 is always located in the arc-shaped groove 330, so that the force-releasing ring 300 can be prevented from being separated from the first hole 111 after the limiting end is removed from the positioning hole 320.

Further, as shown in fig. 5, the depth of the first hole 111 is greater than the thickness of the force-releasing ring 300, and after the positioning hole 320 is matched with the limiting post 730, a gap 113 is kept between the force-releasing ring 300 and the step surfaces formed by the first hole 111 and the second hole 112.

When the nozzle assembly reaches a preset torque during installation, the continuous rotation of the barrel 100 can cause the limit column 730 to be continuously clamped and separated with the plurality of positioning holes 320 until the driving mechanism stops; the long-term collision, engagement or disengagement between the positioning hole 320 and the position-limiting post 730 will cause accelerated wear of the positioning hole 320, and the positioning hole 320 will not receive enough tangential force to drive the force-releasing ring 300 to rotate. In order to reduce the abrasion to the positioning hole 320, when the nozzle assembly is installed to reach a preset torque, an operator can apply a certain thrust to the barrel 100 in the direction of the nozzle assembly when hearing the sound generated by the collision of the first sound or the second sound limiting column 730 with the positioning hole 320, when the limiting column 730 rotates along with the barrel 100 and contacts with the part outside the positioning hole 320, the barrel 100 moves axially relative to the force-releasing ring 300 under the action of the thrust, and the moving distance is less than or equal to the gap 113, so that the axial dislocation of the force-releasing ring 300 of the limiting column 730 relative to the positioning hole 320 can be caused, and the limiting column 730 does not engage with or separate from the subsequent positioning hole 320 along with the rotation of the barrel 100 until the driving mechanism stops; thereby reducing the matching times of the limiting column 730 and the positioning hole 320, effectively reducing the abrasion on the positioning hole 320 and prolonging the service life.

Further, this dismouting frock still includes bearing 600, still is provided with pivot 230 on clamping mechanism 200, and the inner circle of bearing 600 is fixed continuous with pivot 230, and the outer lane of bearing 600 is fixed continuous with second hole 112.

The inner ring of the bearing 600 and the rotating shaft 230 may be in interference fit, and the outer ring of the bearing 600 and the cylinder 100 may also be in interference fit. The bearing 600 can support the clamping mechanism 200 and the housing 400, and prevent the clamping mechanism 200 from shaking.

In addition, when the nozzle assembly is installed, when the nozzle assembly reaches a preset torque, the base 2 and the nozzle 1 do not rotate any more, the barrel 100 continues to rotate, if the clamping mechanism 200 is fixedly connected with the barrel 100, the clamping mechanism 200 can synchronously rotate along with the barrel 100, and as the straight clamping piece 210 on the clamping mechanism 200 is clamped on the nozzle 1, when the clamping mechanism 200 rotates, continuous sliding friction occurs between the straight clamping piece 210 and the nozzle 1, accelerated wear of the nozzle 1 is caused, and the service life of the nozzle 1 is reduced. Therefore, in the embodiment, the clamping mechanism 200 is connected with the cylinder 100 through the bearing 600, so that when the cylinder 100 rotates, the clamping mechanism 200 can be kept still under the action of the bearing 600, thereby completely avoiding the abrasion of the straight clamping piece 210 on the nozzle 1 and prolonging the service life of the nozzle 1.

Further, as shown in fig. 9, in order to ensure the connection reliability between the housing 400 and the clamping mechanism 200, the clamping mechanism 200 further includes a connecting body 220, the straight clip 210 and the rotating shaft 230 are respectively disposed at two sides of the connecting body 220, an external thread is disposed on the connecting body 220, an internal thread is disposed on an inner wall of the housing 400, and the housing 400 is fixedly connected to the connecting body 220 by the matching of the external thread and the internal thread after being sleeved on the straight clip 210.

Further, this dismouting frock still includes drive connecting piece 500, and the one end of keeping away from holding hole 110 on barrel 100 is provided with drive hole 120, and drive connecting piece 500's one end and drive hole 120 are fixed continuous, and drive connecting piece 500's the other end is used for linking to each other with electric tool.

The driving connection member 500 may be a prism with a polygonal cross section, which is a hexagonal prism in this embodiment, and the driving hole 120 may also be a hole with a regular hexagonal cross section, which is matched with the hexagonal prism, and the hexagonal prism may be in interference fit with the driving hole 120. The drive mechanism that controls the rotation of the drive connection 500 may be a power tool, which may be embodied as a power tightening machine, a power torque wrench, or the like.

Further, the dismounting tool further comprises a second spring 820, a second locking bolt 810 and a ball 830, the second spring 820, the second locking bolt 810 and the ball 830 form a second elastic positioning mechanism 800, the side wall of the cylinder 100 is further provided with a second limiting hole 140 and a third limiting hole, the second limiting hole 140, the third limiting hole and the driving hole 120 are sequentially communicated, the second limiting hole 140 and the third limiting hole are coaxial and are perpendicular to the axis of the third limiting hole, the diameter of the second limiting hole 140 is larger than that of the third limiting hole, the ball 830 is arranged in the second limiting hole 140, and part of the ball 830 protrudes from the third limiting hole into the driving hole 120; the two ends of the second spring 820 are respectively abutted against the ball 830 and the second locking bolt 810; the second locking bolt 810 is fixedly connected with the second limiting hole 140; the driving connection member 500 is provided with an annular groove 510, and the annular groove 510 is in snap fit with the ball 830.

When the annular groove 510 does not reach the position aligned with the ball 830 during the insertion of the driving link 500 into the driving hole 120, the ball 830 is retracted into the second stopper hole 140 by the pressing of the sidewall of the driving link 500, and when the annular groove 510 reaches the position aligned with the ball 830, the ball 830 may be caught into the annular groove 510 by the second spring 820, thereby achieving the catching stopper of the driving link 500.

In the above description, the nozzle base 2 is detached or attached, and the nozzle 1 is fixed to the base 2, so that the base 2 and the nozzle 1 can be integrally detached when the base 2 is detached.

However, in some special cases, when the nozzle 1 is damaged, the nozzle base 2 is not damaged, but in view of the limitations of the prior art, the nozzle 1 can be further disassembled only after the base 2 with the nozzle 1 is disassembled, and the nozzle 1 cannot be directly disassembled, so that the disassembling efficiency is reduced, and the base 2 is also easily damaged.

For this reason, as shown in fig. 10 to fig. 15, in another embodiment provided by the present invention, the disassembling tool further includes a locking pin 900, the cylinder 100 is provided with a first locking hole 150 in the radial direction, the clamping mechanism 200 is provided with a second locking hole 221 in the radial direction, and when only the base 2 is disassembled, the locking pin 900 only penetrates through the first locking hole 150 and does not extend into the second locking hole 221.

When only the nozzle 1 needs to be disassembled and assembled, the force unloading ring 300 can be removed from the disassembling and assembling tool, that is, the connection of the force unloading ring 300 and the base 2 is not needed, but the nozzle 1 is directly inserted into the clamping space formed between the inner side surfaces of the plurality of straight clips 210 and used for clamping the nozzle 1, and the clamping of the nozzle 1 is realized through the matching of the straight clips 210 and the shell 400. Then, the locking pin 900 can be simultaneously inserted into the first locking hole 150 and the second locking hole 221 to achieve relative fixation between the cylinder 100 and the clamping mechanism 200, so that in the process of driving the cylinder 100 to rotate, the clamping mechanism 200 can be driven to synchronously rotate through the locking pin 900, thereby driving the nozzle 1 to synchronously rotate, and realizing the dismounting and mounting of the nozzle 1 on the base 2.

That is, when the base 2 is not damaged but the nozzle 1 is damaged, the removal of the nozzle 1 can be achieved by the simultaneous rotation of the clamping mechanism 200, the locking pin 900 and the cylinder 100 without removing the base 2; when the base 2 is damaged, the base 2 can be detached through the cooperation of the force-releasing ring 300, the clamping mechanism 200 and the cylinder 100. From this, this dismouting frock has realized the selective dismouting to nozzle base 2 or nozzle 1, has promoted dismouting efficiency, has also reduced the damage that the dismouting in-process caused.

Specifically, as shown in fig. 13 and 14, the first locking hole 150 includes a lateral groove portion 152 and a straight hole portion 151, the straight hole portion 151 penetrates through the sidewall of the cylinder body 100, the lateral groove portion 152 is recessed inward from the sidewall surface of the cylinder body 100, and one end of the lateral groove portion 152 vertically communicates with one end of the straight hole portion 151; the locking pin 900 includes locking section 910 and bending section 920, and locking section 910 and bending section 920 rotate to be connected, and when the bending section 920 rotated to the collinear position with locking section 910, locking section 910 wore to establish to the second locking hole 221 in, and bending section 920 wore to establish to straight hole portion 151 in to can make barrel 100 and clamping mechanism 200 relatively fixed, in order to realize the dismouting to nozzle 1. The locking segment 910 can be completely or partially inserted into the second locking hole 221, and after the bending segment 920 is inserted into the straight hole 151, the end of the bending segment 920 will not protrude out of the surface of the sidewall of the cylinder 100.

And when the bending section 920 rotates to the position perpendicular to the locking section 910, the locking section 910 penetrates through the straight hole portion 151, the bending section 920 is clamped in the transverse groove portion 152, and at this time, the locking section 910 does not penetrate through the second locking hole 221, so that the cylinder 100 and the clamping mechanism 200 can rotate relatively to realize the disassembly and assembly of the nozzle base 2. After the bending section 920 is clamped in the transverse groove portion 152, the surface of the bending section 920 and the surface of the sidewall of the cylinder 100 may form a complete arc surface.

In order to ensure that the locking pin 900 can be fastened in the second locking hole 221 and prevent the locking pin 900 from falling off during the synchronous rotation of the barrel 100 and the clamping mechanism 200, a partial internal thread may be provided in the second locking hole 221, and a partial external thread may be provided on the locking section 910 of the locking pin 900, so that the locking pin 900 can be fastened in the second locking hole 221 through the cooperation of the internal thread and the external thread. Of course, a partial internal thread may be provided in the first locking hole 150, and the locking section 910 may be screwed with the first locking hole 150, thereby preventing the locking pin 900 from falling off when the cylinder 100 is rotated alone.

A plurality of second locking holes 221 may be uniformly arranged in the circumferential direction of the clamping mechanism 200, so that the alignment of the first locking hole 150 and the second locking hole 221 can be achieved by rotating the cylinder 100 by a small angle.

The embodiment of the utility model provides a little fog nozzle assembly dismouting frock of high pressure has realized the quick assembly disassembly to the nozzle, has promoted dismouting efficiency, the damage to it when also having reduced the dismouting nozzle simultaneously and causing.

Thus, various embodiments of the present disclosure have been described in detail. Some details that are well known in the art have not been described in order to avoid obscuring the concepts of the present disclosure. It will be fully apparent to those skilled in the art from the foregoing description how to practice the presently disclosed embodiments.

Although some specific embodiments of the present disclosure have been described in detail by way of example, it should be understood by those skilled in the art that the foregoing examples are for purposes of illustration only and are not intended to limit the scope of the present disclosure. It will be understood by those skilled in the art that various changes may be made in the above embodiments or equivalents may be substituted for elements thereof without departing from the scope and spirit of the present disclosure. The scope of the present disclosure is defined by the appended claims.

Claims (10)

1. The utility model provides a little fog nozzle assembly dismouting frock of high pressure which characterized in that includes:

the cylinder body (100), a containing hole (110) is arranged in the cylinder body (100), and a first elastic positioning mechanism (700) is arranged on the side wall of the cylinder body (100);

the clamping mechanism (200) is arranged in the accommodating hole (110), a plurality of straight clamping pieces (210) are arranged on the clamping mechanism (200), the straight clamping pieces (210) are uniformly distributed on the circumferential surface, and the straight clamping pieces (210) are gathered and extended towards the axis of the clamping mechanism (200);

the shell (400) is arranged in the accommodating hole (110), the shell (400) is connected with the clamping mechanism (200), an accommodating space is arranged in the shell (400), the straight clamping pieces (210) are arranged in the accommodating space, the outer side surfaces of the straight clamping pieces (210) are abutted to the inner wall of the accommodating space, and a clamping space for clamping the nozzle (1) is formed between the inner side surfaces of the straight clamping pieces (210);

the force unloading ring (300) is arranged in the accommodating hole (110), a plurality of positioning holes (320) are uniformly formed in the side wall of the force unloading ring (300), the positioning holes (320) are matched with the first elastic positioning mechanism (700), and the force unloading ring (300) is further provided with a mounting hole (310) matched with the nozzle base (2).

2. The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly according to claim 1, wherein an inclined surface or an arc surface (211) is arranged on the straight clamping piece (210).

3. The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly according to claim 1, wherein the first elastic positioning mechanism (700) comprises a limiting column (730), a first spring (720) and a first locking bolt (710);

be provided with first spacing hole (130) on the lateral wall of barrel (100), spacing post (730) set up in first spacing hole (130), the spacing end of spacing post (730) stretch out behind first spacing hole (130) with locating hole (320) cooperation, the both ends of first spring (720) respectively with spacing post (730) with first jam bolt (710) butt, first jam bolt (710) with first spacing hole (130) fixed connection.

4. The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly according to claim 3, wherein the accommodating hole (110) comprises a first hole (111) and a second hole (112), the diameter of the first hole (111) is larger than that of the second hole (112), the force unloading ring (300) is arranged in the first hole (111), the clamping mechanism (200) and the shell (400) are arranged in the second hole (112), and the first limiting hole (130) is communicated with the first hole (111).

5. The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly according to claim 4, wherein an arc-shaped groove (330) is formed in the side wall of the force unloading ring (300).

6. The tool for assembling and disassembling the high-pressure micro-mist nozzle assembly according to claim 5, wherein the depth of the first hole (111) is greater than the thickness of the force-releasing ring (300), and after the positioning hole (320) is matched with the limiting column (730), a gap (113) is kept between the force-releasing ring (300) and a step surface formed by the first hole (111) and the second hole (112).

7. The high-pressure micro-mist nozzle assembly dismounting tool according to claim 6, further comprising a bearing (600), wherein a rotating shaft (230) is further arranged on the clamping mechanism (200), an inner ring of the bearing (600) is fixedly connected with the rotating shaft (230), and an outer ring of the bearing (600) is fixedly connected with the second hole (112).

8. The high-pressure micro-mist nozzle assembly dismounting tool according to claim 7, wherein the clamping mechanism (200) further comprises a connecting body (220), the straight clamping piece (210) and the rotating shaft (230) are respectively arranged on two sides of the connecting body (220), an external thread is arranged on the connecting body (220), an internal thread is arranged on an inner wall of the shell (400), and the shell (400) is fixedly connected with the connecting body (220) through the matching of the external thread and the internal thread after being sleeved on the straight clamping piece (210).

9. The tool for disassembling and assembling the high-pressure micro-mist nozzle assembly according to claim 1, further comprising a driving connecting piece (500), wherein a driving hole (120) is formed in one end, far away from the accommodating hole (110), of the cylinder (100), one end of the driving connecting piece (500) is fixedly connected with the driving hole (120), and the other end of the driving connecting piece (500) is used for being connected with an electric tool.

10. The high-pressure micro-mist nozzle assembly dismounting tool according to claim 9, further comprising a second spring (820), a second locking bolt (810) and a ball (830), wherein a second limiting hole (140) and a third limiting hole are further formed in the side wall of the cylinder (100), the second limiting hole (140), the third limiting hole and the driving hole (120) are sequentially communicated, the diameter of the second limiting hole (140) is larger than that of the third limiting hole, the ball (830) is arranged in the second limiting hole (140), and part of the ball (830) protrudes from the third limiting hole into the driving hole (120);

the two ends of the second spring (820) are respectively abutted with the ball (830) and the second locking bolt (810);

the second locking bolt (810) is fixedly connected with the second limiting hole (140);

an annular groove (510) is formed in the driving connecting piece (500), and the annular groove (510) is matched with the ball (830) in a clamping mode.

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