WO2005028354A1 - A locking device for an automatic tube winding apparatus - Google Patents

Abstract

The present invention relates to the technical field of locking devices for a tube winding apparatus, particularly to a locking device for an automatic tube winding apparatus. Whereas the ratchet locking device for the tube winding apparatus in the prior art is not able to lock a flexible tube or cable in any position and can only lock the flexible tube or cable periodically, and the locking operation of it is not easy, the present invention provides a locking device for an automatic tube winding apparatus, which can lock the flexible tube or cable in any position conveniently and easily during the winding or rewinding operation. The locking device includes a connector rotating shaft, housing, and a grooved cylindrical cam assembly. A projection is provided on the wall of an inner hole in said housing. Said grooved cylindrical cam assembly includes a grooved cylindrical cam, a spring and a transmission sleeve. An A-shaped groove engagable with said projection is provided on the outer surface of said grooved cylindrical cam. Said grooved cylindrical cam assembly is disposed in the inner hole in said housing, and said connector rotating shaft is inserted in the inner hole of said transmission sleeve.

Description

 TECHNICAL FIELD

 The present invention relates to the technical field of a pipeline winder locking device, and particularly to a pipeline winder locking device for an automatic pipeline winder. Background technique .

 A conventional locking device in a pipe winder for storing hoses or cables is a ratchet type locking device. The existing ratchet-type locking device of the tube winder has inconvenience in use. In use, the hose or cable can only be locked periodically, and the hose or cable cannot be locked at any position. The lack of easy locking operation Place. Summary of the invention

 The present invention is directed to the inconvenience of the existing ratchet-type locking device of the pipeline winder, and can only be used to periodically lock the hose or the cable during use. The hose or the cable cannot be locked at any position, and the locking operation is not easy. The shortcomings of grasping are to provide a pipeline automatic winder locking device which is convenient to use, easy to lock and can be locked arbitrarily when the hose or cable is pulled out or retracted.

 The technical solution adopted in the present invention is completed in the following manner: The automatic winding device locking device for a pipeline of the present invention includes a connecting member rotating shaft, a housing, and a grooved cylindrical cam assembly. A boss is provided on the connecting member shaft, and a boss is provided on the inner hole wall of the housing, wherein the grooved cylindrical cam assembly includes a grooved cylindrical cam, a spring, and a transmission sleeve on the inner hole wall of the transmission sleeve. The groove is matched with the projection on the rotating shaft of the connecting piece. The grooved cylindrical cam is composed of a cam body and a cam retaining ring. The grooved cylindrical cam is provided with a spring fixing hole and a slide groove. An A-shaped groove for guiding the protrusion on the inner hole wall of the housing is provided on the outer surface, and the groove is configured to allow the protrusion to circulate in a single direction therein, and the spring is sleeved on the transmission sleeve to make the spring The inner peripheral surface of the transmission sleeve is in full contact with the outer peripheral surface of the transmission sleeve. The spring and the transmission sleeve are fixed in the shaft hole of the grooved cylindrical cam through the cam body and the cam ring. A fixed end of the spring is fixed in the spring fixing hole of the grooved cylindrical cam. The other free end of the spring is inserted into the groove of the grooved cylindrical cam without restriction. The grooved cylindrical cam assembly is installed in the inner hole of the housing, and the protrusion on the wall of the inner hole of the housing and the grooved cylindrical cam. Mating grooves The connecting member shaft is inserted into the inner hole of the transmission sleeve, and the projection on the connecting member shaft and the groove on the inner wall of the transmission sleeve cooperate to allow axial relative movement between the connecting member shaft and the transmission sleeve.

During installation, the other end of the connecting member's rotating shaft is connected to the winding wheel on the automatic pipeline winder, and the shell is connected to the wheel cover on the automatic pipeline winder. When the hose or cable is pulled out, the connector shaft automatically winds with the pipeline. The winding wheel on the device rotates in the opposite direction of the spring winding direction (that is, the winding direction of the spring from its fixed end to its free end). The projection on the wall of the inner hole of the housing moves to and stops on the grooved cylindrical cam. At the point A of the groove, at this moment, the spring is not held tightly on the outer peripheral surface of the transmission sleeve and is in a loose state, allowing the transmission sleeve to be driven to rotate by the rotation shaft of the connecting member, and the grooved cylindrical cam and the spring are in a relatively static state. -When pulling the hose or cable, due to the rewinding force of the automatic winder of the pipeline, the protrusion on the wall of the hole in the housing moves to and stops at the point B of the groove on the grooved cylindrical cam, and Driven by the rewinding force of the connecting member, the rotating shaft of the connecting member tends to rotate in the same rotation direction as that of the spring, so that the spring is held tightly on the outer peripheral surface of the transmission sleeve. Therefore, the connecting member rotating shaft, grooved cylindrical cam, and transmission sleeve The springs are in a relatively static state. At this time, the hose or cable cannot be retracted and is in a locked state. When the hose or cable is pulled again, the protrusion on the inner wall of the housing moves to and stops at the point C of the groove on the grooved cylindrical cam. At this time, the state is in the groove with the protrusion on the inner wall of the housing. The state of the groove A on the cylindrical cam is the same, and the hose or cable can be pulled out. When pulling the hose or cable again, the protrusion on the wall of the inner hole of the housing moves to the position of the point D of the groove on the grooved cylindrical cam under the action of the rewinding force. At this time, it is inserted into the grooved cylindrical cam. The free end of the spring in the chute is abutted by the protrusion on the wall of the hole in the housing, so that the spring is loosened without clinging to the outer peripheral surface of the transmission sleeve. At this time, the transmission sleeve rotates along the shaft of the connecting member, and the hose or cable The line can retract.

 Compared with the existing ratchet-type locking device of the pipeline winder, the present invention has the characteristics of convenient use, easy locking operation, and arbitrary locking when the hose or cable is pulled out or retracted. The invention is particularly suitable as a locking device in a pipeline winder for storing hoses or cables. BRIEF DESCRIPTION OF THE DRAWINGS

 Figure 1 is an exploded view of the automatic winder locking device of the pipeline.

 FIG. 2 is a schematic structural diagram of a pipeline automatic winder locking device.

 Fig. 3 is a schematic structural diagram of a casing.

 FIG. 4 is a structural diagram of a cam body.

 FIG. 5 is a left side view of FIG. 4.

 FIG. 6 is a right side view of FIG. 4.

 FIG. 7 is a structural diagram of a cam retaining ring.

 FIG. 8 is a left side view of FIG. 7.

 Fig. 9 is a perspective view of a grooved cylindrical cam.

 Fig. 10 is a structural diagram of a transmission sleeve.

 Fig. 11 is a sectional view taken along the line A-A of Fig. 10.

FIG. 12 is a schematic diagram of a motion path of a protrusion in a groove of a grooved cylindrical cam groove. FIG. 13 is an exploded view of a combination of a pipeline automatic winder locking device and a gear transmission structure according to the present invention. -DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS---The following further describes the present invention through embodiments with reference to the accompanying drawings.

1 to 12 of the accompanying drawings, a pipeline automatic winder locking device includes a connecting member rotating shaft 1, a housing 2, a grooved cylindrical cam assembly, a protrusion is provided on the connecting member rotating shaft 1, and a housing A convex head _{7 is} provided on the inner hole wall of 2, wherein the grooved cylindrical cam assembly includes a grooved cylindrical cam, a spring 4, and a transmission sleeve 5, and an inner wall of the transmission sleeve 5 is provided with a connecting member 1 on the rotation shaft 1. The groove 11 matched with the convex block is provided with a shoulder 12 on the outer surface of the transmission sleeve 5. The grooved cylindrical cam is composed of the cam body 3 and the cam retaining ring 6. The grooved cylindrical cam is provided with a spring fixing hole. 9 and chute 10, a groove A of generally A-shape is provided on the outer surface of the grooved cylindrical cam for guiding the protrusion 7, and the shape of the groove is configured to allow the protrusion 7 only in a single direction. The spring 4 is cyclically moved; the spring 4 is sleeved on the transmission sleeve 5 so that the inner peripheral surface of the spring 4 and the outer peripheral surface of the transmission sleeve 5 are sufficiently in contact with each other. The spring 4 may be formed by winding a rectangular steel wire with a cross section, for example, so that the spring 4 and There is sufficient contact between the transmission sleeve 5 and the spring 4 and the transmission sleeve 5 through the cam body 3 and the projection The retaining ring 6 is fixed in the shaft hole of the grooved cylindrical cam, wherein one fixed end of the spring 4 is fixed in the spring fixed hole 9 of the grooved cylindrical cam, and the other free end of the spring 4 is inserted in the unconstrained In the slot 10 of the grooved cylindrical cam, when the transmission sleeve 5 tries to rotate relative to the spring 4 in the same direction as the spring, the spring 4 holds the transmission sleeve 5 tightly, and when the transmission sleeve 5 tries to rotate relative to the spring 4 When rotating in a direction opposite to the direction of the spring, the spring 4 loosens the hold on the transmission sleeve 5 and allows the transmission sleeve 5 to rotate relative to the spring 4. The grooved cylindrical cam assembly is installed in the inner hole of the housing 2, The protrusion 7 on the inner hole wall of the housing 2 is matched with the groove 8 on the grooved cylindrical cam; the connecting member rotating shaft 1 is inserted into the inner hole of the transmission sleeve 5, and the protrusion on the connecting member rotating shaft 1 and the transmission sleeve 5 The groove 11 on the wall of the inner hole cooperates to allow axial relative movement between the connecting member rotating shaft 1 and the transmission sleeve 5 so as to adapt the protrusion 7 on the wall of the inner hole of the housing 2 to the groove of the grooved cam The loop moves in 8. During installation, the other end of the connecting member rotating shaft 1 is connected to the winding wheel on the automatic pipeline winder, and the casing 2 is connected to the fixed wheel cover on the automatic pipeline winder.

FIG. 13 shows a combination of the automatic winder locking device of the present invention and a gear transmission structure. When the design of the pipeline automatic winder has a large rewinding force (a large rewinding force is often required when the hose or cable to be retracted is very long), in order to increase the locking torque, the locking device of the present invention is not directly The connecting member shaft 1 is connected to the winding wheel of the automatic pipeline winder, but as shown in FIG. 13, the locking device of the present invention can be installed so that its axis X and the winding wheel of the automatic pipeline winder are installed. The axes Y are parallel (that is, different axes), and the rotating shaft 1 of the connecting member passes a reduction transmission mechanism, here is a pair of transmission gears of different meshes meshing with each other 13 and 14 are engaged with the winding wheel to transmit torque. The "reduction transmission" here means that when rotation is transmitted from one component (such as the connecting member shaft 1) to another component (such as the winding wheel), the speed of the transmission is reduced, that is, the torque transmitted is increased. In this case, the housing 2 of the locking device of the present invention can be fixed on a fixed part of the automatic pipeline winder, the transmission gear 13 is coaxially fixed on the connecting member rotating shaft 1, and the transmission gear 14 is coaxial. It is fixedly installed on the winding wheel, and the radius of the transmission gear 13 on the connecting member shaft 1 is smaller than the radius of the transmission gear 14 on the winding wheel. In addition, as an equivalent manner, the locking device of the present invention is also installed so that its axis X is parallel to the axis Y of the winding wheel of the pipeline automatic winder, and the transmission gear 13 is coaxially fixed to the connecting member shaft. The only difference is that the housing 2 of the locking device is fixedly connected to the winding wheel of the automatic pipeline winder, and the transmission gear 14 and the winding wheel are fixedly connected to the automatic winding of the pipeline coaxially. At this time, at this time, the connecting member shaft 1 attempts to transmit the torque to the fixed part of the pipeline automatic winder through the reduction transmission mechanism. The transmission gear 13 is equivalent to a planetary gear that rotates around the transmission gear as the winding wheel rotates. The axis of 14 revolves. Since the radius of the transmission gear 13 on the connecting member rotating shaft 1 is smaller than the radius of the transmission gear 14. on the winding wheel, the locking device of the present invention can lock the winding wheel with a small stopping force to overcome the rewinding force. Thereby, the winding wheel of the pipeline automatic winder can be locked more effectively and reliably. Regarding the structure and operation mode of the locking device itself, they are the same as those described above with reference to FIGS. 1 to 12. Of course, it is clear to those skilled in the art that the above-mentioned reduction transmission mechanism may also include other equivalent mechanisms such as a reduction sprocket transmission mechanism and a reduction belt transmission mechanism.

Claims

Claim

1. A pipeline automatic winder locking device, which comprises a connecting member shaft, a housing, and a grooved cylindrical cam assembly. A protrusion is provided on an inner hole wall of the housing, and the grooved cylindrical cam assembly includes a groove. Cylindrical cam, spring, transmission sleeve, grooved cylindrical cam is composed of cam body and cam retaining ring. The grooved cylindrical cam is provided with spring fixing holes and slide grooves. The outer surface of the grooved cylindrical cam is provided with a guide shell. The groove of the protrusion on the wall of the body is configured to allow the protrusion to cyclically move in a single direction therein, and the spring is sleeved on the transmission sleeve so that the inner peripheral surface of the spring and the outer peripheral surface of the transmission sleeve are in full contact. The spring and the transmission sleeve are fixed in the shaft hole of the grooved cylindrical cam through the cam body and the cam retaining ring. One fixed end of the spring is fixed in the spring fixed hole of the grooved cylindrical cam. The other free end of the spring is inserted in the unconstrained In the chute of the grooved cylindrical cam, the grooved cylindrical cam assembly is installed in the inner hole of the housing, and the protrusion on the wall of the inner hole of the housing matches the groove on the grooved cylindrical cam. Moving the inner bore of the sleeve member connected to rotate with the shaft and the drive sleeve, 'while permitting relative axial movement between the connecting shaft and drive sleeve member.

 2. The automatic winder locking device for a pipeline according to claim 1, wherein the groove on the outer surface of the grooved cylindrical cam is A-shaped. .

 3. The automatic winding device locking device for a pipeline according to claim 1 or 2, characterized in that a projection is provided on the connecting member rotating shaft, and an inner hole wall of the transmission sleeve is provided with a projection on the connecting member rotating shaft. The groove on the shaft of the connecting piece matches the groove on the inner hole wall of the transmission sleeve.

 4. An automatic pipeline winder having a winding wheel for winding a pipeline and a locking device according to claim 1, wherein the locking device is installed coaxially with the winding wheel, and the locking device The casing is connected to a fixed part in the automatic pipeline winder, and the connecting member rotating shaft of the locking device is coaxially connected to the winding wheel of the automatic pipeline winder.

 5. An automatic pipeline winder, comprising a winding wheel for winding a pipeline, and a locking device according to claim 1, wherein the locking device is installed in parallel with the winding wheel in different axes, The housing of the locking device is connected to a fixed part of the automatic pipeline winder. The connecting member rotating shaft of the locking device is engaged with the winding wheel of the automatic pipeline winder through a reduction transmission mechanism to transmit torque.

 6. The automatic pipeline winder according to claim 5, wherein the reduction transmission mechanism comprises a first gear coaxially fixedly mounted on the rotating shaft of the connecting member of the locking device and a coaxially fixedly mounted on the pipeline The second gear of the winding wheel of the automatic winder, the first gear and the second gear mesh with each other, and the radius of the first gear is smaller than that of the second gear.

7. An automatic pipeline winder, comprising a winding wheel for winding a pipeline, and a locking device according to claim 1, wherein the locking device is installed in parallel with the winding wheel in different axes, Locking device The casing is fixedly connected to the winding wheel of the automatic pipeline winder, and the connecting member rotating shaft of the locking device is engaged with a fixed part of the automatic pipeline winder through a reduction transmission mechanism to transmit torque.

 8. The automatic pipeline winder according to claim 7, wherein the reduction transmission mechanism comprises a first gear coaxially fixedly mounted on a rotating shaft of a connecting member of the locking device, and a coil with the automatic pipeline winder. The second gear is coaxial with the winding wheel and fixedly connected to the fixed part of the pipeline automatic winder, the first gear and the second gear mesh with each other, and the radius of the first gear is smaller than that of the second gear.