CN110480517B - Water flow surrounding impact type wire deburring device - Google Patents

Abstract

The invention discloses a water flow surrounding impact type wire deburring device which comprises a main body shell. The device forms a high-pressure impact state by utilizing water flow circulating inside, can perform comprehensive impact action on the side surface of a lead in a 360-degree rotation mode during impact to polish burrs, has small damage to the surface of the lead due to the fact that the impact is in the water flow mode, has a gear set meshed type rotation direction differentiation mechanism, can realize rotation differentiation functions of different planes, and achieves multiple purposes, is provided with an annular array spiral spring type maximum rotation strength control mechanism to prevent the driving motor from being damaged due to overlarge liquid resistance, and is provided with a conical gear set meshed type vertical angle connecting mechanism to achieve the rotation transmission action of a vertical angle.

Description

Water flow surrounding impact type wire deburring device

Technical Field

The invention relates to the technical field of power equipment, in particular to a water flow surrounding impact type wire deburring device.

Background

At present, the copper wire portion in the wire has a structure such as burr on the surface after manufacture, which affects the physical properties of the wire, and therefore, it is necessary to remove the copper wire portion before forming a finished product.

Disclosure of Invention

The invention aims to provide a water flow surrounding impact type wire deburring device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a water flow surrounding impact type wire deburring device comprises a main body shell, wherein a main first hollow structure is arranged at the center of the upper end inside the main body shell, a main second hollow structure and a main third hollow structure are respectively arranged on two sides of the main first hollow structure inside the main body shell, a main through hole structure communicated with the outside and the main second hollow structure and the main third hollow structure is arranged inside the main body shell, an annular installation space is arranged at the center of the inner wall of the main first hollow structure, an annular hollow shell is installed on the inner wall of the annular installation space through a main bearing and a sealing ring, a liquid reserved space is arranged on the outer ring of the annular hollow shell, a plurality of water flow nozzles are installed on the inner ring of the annular hollow shell, and a connecting pipeline body is installed at one end of the annular hollow shell facing the main first hollow structure, a conical hollow structure is arranged in one end of the connecting pipeline body, a main liquid discharge hole communicated with a liquid reserved space is arranged in the bottom end of the main body shell, a funnel-shaped structure is arranged at the bottom of a main third hollow structure, a turbine installation space is arranged at the bottom of the main liquid discharge hole, a main liquid inlet hole of the funnel-shaped structure and the center of the bottom of the internal turbine installation space of the main body shell, a main part installation space is arranged on one side of the turbine installation space, a gear set meshed type rotation direction differentiation mechanism is arranged in the main part installation space, a main first rotating shaft, a main second rotating shaft and a main third rotating shaft are respectively arranged on the two sides and above the gear set meshed type rotation direction differentiation mechanism, the top end of the main third rotating shaft is meshed with the side surface of the connecting pipeline body through a conical gear set meshed type vertical angle connecting mechanism, the one end of main second rotation axis installs a circular array coil spring maximum rotation intensity control mechanism, a main fourth rotation axis of circular array coil spring maximum rotation intensity control mechanism's tip center installation, the turbine is installed at the one end that is located turbine installation space inside to main fourth rotation axis.

Further, the gear train meshing type rotation direction differentiation mechanism comprises a hollow shell for the gear train meshing type rotation direction differentiation mechanism, a connecting plate for the gear train meshing type rotation direction differentiation mechanism, a bolt hole for the gear train meshing type rotation direction differentiation mechanism, a hollow structure for the gear train meshing type rotation direction differentiation mechanism, a first rotating shaft for the gear train meshing type rotation direction differentiation mechanism, a first bearing for the gear train meshing type rotation direction differentiation mechanism, a main gear for the gear train meshing type rotation direction differentiation mechanism, a second rotating shaft for the gear train meshing type rotation direction differentiation mechanism, a secondary gear for the gear train meshing type rotation direction differentiation mechanism and a second bearing for the gear train meshing type rotation direction differentiation mechanism; a gear set meshed connecting plate for a rotation direction differentiation mechanism is mounted at the bottom of the hollow shell for the gear set meshed rotation direction differentiation mechanism, a plurality of gear set meshed bolt holes for a rotation direction differentiation mechanism are formed in the gear set meshed connecting plate for the rotation direction differentiation mechanism, a hollow structure for the gear set meshed rotation direction differentiation mechanism is arranged at the center of the inner part of the hollow shell for the gear set meshed rotation direction differentiation mechanism, a first rotating shaft for the gear set meshed rotation direction differentiation mechanism is mounted at the center of the bottom of the hollow shell for the gear set meshed rotation direction differentiation mechanism through a first bearing for the gear set meshed rotation direction differentiation mechanism at a penetrating part, and a first bearing for the gear set meshed rotation direction differentiation mechanism is mounted at the top of the first rotating shaft for the gear set meshed rotation direction differentiation mechanism, the gear set meshed type main gear for the rotation direction differentiation mechanism is mounted at the top end of a first rotating shaft for the gear set meshed type rotation direction differentiation mechanism, the side face of a hollow shell for the gear set meshed type rotation direction differentiation mechanism is penetrated through by a plurality of second rotating shafts for the gear set meshed type rotation direction differentiation mechanism, the gear set meshed type main gear for the rotation direction differentiation mechanism and the gear set meshed type main gear for the rotation direction differentiation mechanism are mounted at penetrating positions through second bearings for the gear set meshed type rotation direction differentiation mechanism, a secondary gear for the gear set meshed type rotation direction differentiation mechanism is mounted at one end of each second rotating shaft for the gear set meshed type rotation direction differentiation mechanism, and the secondary gear for the gear set meshed type rotation direction differentiation mechanism and the main gear for the gear set meshed type rotation direction differentiation mechanism are meshed through tooth structures.

Furthermore, the outer ends of the second rotating shafts for the two gear set meshed type rotation direction differentiation mechanisms are respectively connected with one end of the main first rotating shaft and one end of the main second rotating shaft, and the end parts of the first rotating shafts for the gear set meshed type rotation direction differentiation mechanisms are connected with the end parts of a main third rotating shaft.

Further, the gear train meshing type rotation direction differentiating mechanism connecting plate is mounted inside the main component mounting space by a bolt inserted into the gear train meshing type rotation direction differentiating mechanism bolt hole.

Further, the coil spring type maximum rotation strength control mechanism of the ring array comprises a main hollow shell for the coil spring type maximum rotation strength control mechanism of the ring array, a main hollow section for the coil spring type maximum rotation strength control mechanism of the ring array, a rotary column for the coil spring type maximum rotation strength control mechanism of the ring array, a semicircular groove structure for the coil spring type maximum rotation strength control mechanism of the ring array, an auxiliary hollow section for the coil spring type maximum rotation strength control mechanism of the ring array, a movable plate for the coil spring type maximum rotation strength control mechanism of the ring array, a coil spring for the coil spring type maximum rotation strength control mechanism of the ring array and a push rod for the coil spring type maximum rotation strength control mechanism of the ring array; the center of one end face of a main hollow shell for the ring array helical spring type maximum rotation strength control mechanism is fixedly connected with the end part of a main second rotating shaft, the center inside the main hollow shell for the ring array helical spring type maximum rotation strength control mechanism is a main hollow section for the ring array helical spring type maximum rotation strength control mechanism, the main hollow shell for the ring array helical spring type maximum rotation strength control mechanism is positioned in the main hollow section for the ring array helical spring type maximum rotation strength control mechanism, a rotating column for the ring array helical spring type maximum rotation strength control mechanism is sleeved inside the main hollow section for the ring array helical spring type maximum rotation strength control mechanism, an auxiliary hollow section for the ring array helical spring type maximum rotation strength control mechanism is arranged inside the auxiliary hollow section for the ring array helical spring type maximum rotation strength control mechanism A movable plate for the coil spring array type maximum rotary strength control mechanism is placed on one end face of a main hollow section for the coil spring array type maximum rotary strength control mechanism, a coil spring for the coil spring array type maximum rotary strength control mechanism is fixed between one ends of the movable plates for the coil spring array type maximum rotary strength control mechanism in an auxiliary hollow section for the coil spring array type maximum rotary strength control mechanism, a push rod for the coil spring array type maximum rotary strength control mechanism of an integrated structure with the movable plate is arranged on one end face of the movable plate for the coil spring array type maximum rotary strength control mechanism, and the push rod for the coil spring array type maximum rotary strength control mechanism penetrates through the main hollow shell for the coil spring array type maximum rotary strength control mechanism, and the side surface of the rotary column for the annular array helical spring type maximum rotary strength control mechanism is provided with a semicircular groove structure for the annular array helical spring type maximum rotary strength control mechanism, which is used for placing the end part of the push rod for the annular array helical spring type maximum rotary strength control mechanism, and one end of the rotary column for the annular array helical spring type maximum rotary strength control mechanism is fixed with the end part of a main fourth rotary shaft.

Further, the initial length of the coil spring for the maximum rotational strength control mechanism of the ring array coil spring is longer than the length of the auxiliary hollow section for the maximum rotational strength control mechanism of the ring array coil spring.

Furthermore, the structural shape of the end part of the push rod for the annular array helical spring type maximum rotation strength control mechanism is consistent with the structural shape of the semicircular groove structure for the annular array helical spring type maximum rotation strength control mechanism.

Furthermore, the meshing type vertical angle connecting mechanism of the bevel gear set comprises a first bevel gear for the meshing type vertical angle connecting mechanism of the bevel gear set, a shaft body mounting hole for the meshing type vertical angle connecting mechanism of the bevel gear set, a second bevel gear for the meshing type vertical angle connecting mechanism of the bevel gear set and a central hole for the meshing type vertical angle connecting mechanism of the bevel gear set; the first bevel gear for the conical gear set meshing type vertical angle connecting mechanism is provided with a shaft body mounting hole at the bottom center, the second bevel gear for the conical gear set meshing type vertical angle connecting mechanism is bonded to the side face of the first bevel gear for the conical gear set meshing type vertical angle connecting mechanism through a tooth structure, and the center of the second bevel gear for the conical gear set meshing type vertical angle connecting mechanism is provided with a central hole for the conical gear set meshing type vertical angle connecting mechanism.

Furthermore, a main third rotating shaft is installed inside the shaft body installation hole for the bevel gear set meshing type vertical angle connecting mechanism.

Furthermore, one end surface of the second bevel gear of the bevel gear set meshing type vertical angle connecting mechanism is fixedly connected with the end part of the connecting pipeline body.

Compared with the prior art, the invention has the beneficial effects that: the device forms a high-pressure impact state by utilizing water flow circulating inside, can perform comprehensive impact action on the side surface of a lead in a 360-degree rotation mode during impact to polish burrs, has small damage to the surface of the lead due to the fact that the impact is in the water flow mode, has a gear set meshed type rotation direction differentiation mechanism, can realize rotation differentiation functions of different planes, and achieves multiple purposes, is provided with an annular array spiral spring type maximum rotation strength control mechanism to prevent the driving motor from being damaged due to overlarge liquid resistance, and is provided with a conical gear set meshed type vertical angle connecting mechanism to achieve the rotation transmission action of a vertical angle.

Drawings

FIG. 1 is a schematic diagram of a full-section structure of a water flow surrounding impact type wire deburring device of the present invention;

FIG. 2 is a schematic structural diagram of a gear-set meshing type rotation direction differentiation mechanism in a water flow surrounding impact type wire deburring device according to the present invention;

FIG. 3 is a schematic structural diagram of a maximum rotation strength control mechanism of a circular array coil spring type in a water flow surrounding impact type wire deburring device according to the present invention;

FIG. 4 is a schematic structural diagram of a meshing type vertical angle connecting mechanism of a bevel gear set in a water flow surrounding impact type wire deburring device according to the present invention;

in the figure: 1, a main body housing, 2, a main first hollow structure, 3, a main second hollow structure, 4, a main third hollow structure, 5, a main through hole structure, 6, an annular mounting space, 7, an annular hollow housing, 8, a liquid reserving space, 9, a water flow nozzle, 10, a connecting pipe body, 11, a tapered hollow structure, 12, a main drainage hole, 13, a turbine mounting space, 14, a main liquid inlet hole, 15, a funnel structure, 16, a main first rotation axis, 17, a main part mounting space, 18, a gear train meshing type rotation direction differentiating mechanism, 181, a gear train meshing type rotation direction differentiating mechanism hollow housing, 182, a gear train meshing type rotation direction differentiating mechanism connecting plate, 183, a gear train meshing type rotation direction differentiating mechanism bolt hole, 184, a gear train meshing type rotation direction differentiating mechanism hollow structure, 185, a gear train meshing type rotation direction differentiating mechanism first rotation axis, 186, a first bearing for a gear train meshing type rotation direction differentiating mechanism, 187, a main gear for a gear train meshing type rotation direction differentiating mechanism, 188, a second rotating shaft for a gear train meshing type rotation direction differentiating mechanism, 189, a pinion for a gear train meshing type rotation direction differentiating mechanism, 1810, a second bearing for a gear train meshing type rotation direction differentiating mechanism, 19, a main second rotating shaft, 20, a ring array coil spring type maximum rotation strength controlling mechanism, 201, a main hollow housing for a ring array coil spring type maximum rotation strength controlling mechanism, 202, a main hollow section for a ring array coil spring type maximum rotation strength controlling mechanism, 203, a rotating column for a ring array coil spring type maximum rotation strength controlling mechanism, 204, a semicircular groove structure for a ring array coil spring type maximum rotation strength controlling mechanism, 205, a sub hollow section for a ring array coil spring type maximum rotation strength controlling mechanism, 206, a movable plate for a ring array coil spring type maximum rotation strength control mechanism, 207, a coil spring for a ring array coil spring type maximum rotation strength control mechanism, 208, a push rod for a ring array coil spring type maximum rotation strength control mechanism, 21, a main fourth rotation shaft, 22, a turbine, 23, a main third rotation shaft, 24, a bevel gear set meshing type vertical angle connecting mechanism, 241, a first bevel gear for a bevel gear set meshing type vertical angle connecting mechanism, 242, a shaft body mounting hole for a bevel gear set meshing type vertical angle connecting mechanism, 243, a second bevel gear for a bevel gear set meshing type vertical angle connecting mechanism, 244, a central hole for a bevel gear set meshing type vertical angle connecting mechanism.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: the device comprises a main body shell 1, wherein a main first hollow structure 2 is arranged at the center of the upper end in the main body shell 1, a main second hollow structure 3 and a main third hollow structure 4 are respectively arranged at two sides of the main first hollow structure 2 in the main body shell 1, a main through hole structure 5 for communicating the outside with the main second hollow structure 3 and the main third hollow structure 4 is arranged in the main body shell 1, an annular installation space 6 is arranged at the center of the inner wall of the main first hollow structure 2, an annular hollow shell 7 is arranged on the inner wall of the annular installation space 6 through a main bearing and a sealing ring, a liquid reserved space 8 is arranged on the outer ring of the annular hollow shell 7, a plurality of water flow nozzles 9 are arranged on the inner ring of the annular hollow shell 7, and a connecting pipeline body 10 is arranged at one end of the annular hollow shell 7 facing the main first hollow structure 3, a conical hollow structure 11 is arranged in one end of the connecting pipeline body 10, a main liquid discharge hole 12 communicated with the liquid reserved space 8 is arranged in the bottom end of the main body shell 1, a funnel-shaped structure 15 is arranged at the bottom of the main third hollow structure 4, a turbine installation space 13 is arranged at the bottom of the main liquid discharge hole 12, the center of the bottom of the internal turbine installation space 13 of the main body shell 1 and a main liquid inlet hole 14 of the funnel-shaped structure 15 are arranged, a main part installation space 17 is arranged at one side of the turbine installation space 13, a gear set meshed type rotation direction differentiation mechanism 18 is arranged in the main part installation space 17, a main first rotating shaft 16, a main second rotating shaft 19 and a main third rotating shaft 23 are respectively arranged at two sides and above the gear set meshed type rotation direction differentiation mechanism 18, the top end of the main third rotating shaft 23 is meshed with the side surface of the connecting pipeline body 10 through a conical gear set meshed type vertical angle connecting mechanism 24, an annular array helical spring type maximum rotation strength control mechanism 20 is installed at one end of the main second rotating shaft 19, a main fourth rotating shaft 21 is installed at the center of the end portion of the annular array helical spring type maximum rotation strength control mechanism 20, and a turbine 22 is installed at one end, located inside the turbine installation space 13, of the main fourth rotating shaft 21.

Referring to fig. 2, the gear train meshing type rotation direction differentiation mechanism 18 includes a gear train meshing type rotation direction differentiation mechanism hollow housing 181, a gear train meshing type rotation direction differentiation mechanism connecting plate 182, a gear train meshing type rotation direction differentiation mechanism bolt hole 183, a gear train meshing type rotation direction differentiation mechanism hollow structure 184, a gear train meshing type rotation direction differentiation mechanism first rotating shaft 185, a gear train meshing type rotation direction differentiation mechanism first bearing 186, a gear train meshing type rotation direction differentiation mechanism main gear 187, a gear train meshing type rotation direction differentiation mechanism second rotating shaft 188, a gear train meshing type rotation direction differentiation mechanism pinion 189, and a gear train meshing type rotation direction differentiation mechanism second bearing 1810; a gear train meshing type connecting plate 182 for the rotation direction differentiation mechanism is mounted on the bottom of the gear train meshing type hollow housing 181, a plurality of gear train meshing type bolt holes 183 for the rotation direction differentiation mechanism are provided in the gear train meshing type connecting plate 182, a gear train meshing type hollow structure 184 for the rotation direction differentiation mechanism is provided in the center of the gear train meshing type hollow housing 181, a first rotating shaft 185 for the gear train meshing type rotation direction differentiation mechanism is mounted on the center of the bottom of the gear train meshing type hollow housing 181, and both are mounted at the penetrating position by a first bearing 186 for the gear train meshing type rotation direction differentiation mechanism, a first bearing 186 for the gear train meshing type rotation direction differentiation mechanism is mounted on the top of the first rotating shaft 185 for the gear train meshing type rotation direction differentiation mechanism, a gear train meshing type main gear 187 for a rotation direction differentiation mechanism is mounted on the top end of the first rotation shaft 185 for a gear train meshing type hollow housing 181, the side surface of the gear train meshing type hollow housing 181 is penetrated by a plurality of second rotation shafts 188 for a gear train meshing type rotation direction differentiation mechanism, and both are mounted through a second bearing 1810 for a gear train meshing type rotation direction differentiation mechanism at the penetrating position, a pinion 189 for a gear train meshing type rotation direction differentiation mechanism is mounted on one end of each second rotation shaft 188 for a gear train meshing type rotation direction differentiation mechanism, and the pinion 189 for a gear train meshing type rotation direction differentiation mechanism and the main gear 187 for a gear train meshing type rotation direction differentiation mechanism are meshed through a tooth structure; the outer ends of the second rotating shafts 188 for the two gear-set meshing type rotation direction differentiating mechanisms are respectively connected with one ends of the main first rotating shaft 16 and the main second rotating shaft 19, and the end parts of the first rotating shafts 185 for the gear-set meshing type rotation direction differentiating mechanisms are connected with the end parts of a main third rotating shaft 23; the gear train meshing type connecting plate 182 for the rotation direction differentiation mechanism is mounted inside the main part mounting space 17 by bolts inserted into the gear train meshing type bolt holes 183 for the rotation direction differentiation mechanism, and mainly functions as: the gear engagement is utilized, and the multipurpose of one machine is realized.

Referring to fig. 3, the helical coil spring type maximum rotation strength control mechanism 20 includes a main hollow housing 201 for the helical coil spring type maximum rotation strength control mechanism, a main hollow section 202 for the helical coil spring type maximum rotation strength control mechanism, a rotary column 203 for the helical coil spring type maximum rotation strength control mechanism, a semicircular groove structure 204 for the helical coil spring type maximum rotation strength control mechanism, an auxiliary hollow section 205 for the helical coil spring type maximum rotation strength control mechanism, a movable plate 206 for the helical coil spring type maximum rotation strength control mechanism, a helical spring 207 for the helical coil spring type maximum rotation strength control mechanism, and a push rod 208 for the helical coil spring type maximum rotation strength control mechanism; the center of one end face of the main hollow casing 201 for the helical spring array type maximum rotation strength control mechanism is fixedly connected with the end part of a main second rotating shaft 19, the center of the inside of the main hollow casing 201 for the helical spring array type maximum rotation strength control mechanism is a main hollow section 202 for the helical spring array type maximum rotation strength control mechanism, a rotary column 203 for the helical spring array type maximum rotation strength control mechanism is sleeved in the main hollow casing 201 for the helical spring array type maximum rotation strength control mechanism in the main hollow section 202 for the helical spring array type maximum rotation strength control mechanism, an auxiliary hollow section 205 for the helical spring array type maximum rotation strength control mechanism is arranged in the main hollow casing 201 for the helical spring array type maximum rotation strength control mechanism, the inside of the secondary hollow section 205 for the helical coil spring type maximum rotation strength control mechanism is located at one end face of the primary hollow section 202 for the helical coil spring type maximum rotation strength control mechanism, a movable plate 206 for the helical coil spring type maximum rotation strength control mechanism is placed at one end face of the secondary hollow section 205 for the helical coil spring type maximum rotation strength control mechanism, a helical spring 207 for the helical coil spring type maximum rotation strength control mechanism is fixed between one ends of the movable plates 206 for the helical coil spring type maximum rotation strength control mechanism, one end face of the movable plate 206 for the helical coil spring type maximum rotation strength control mechanism is provided with a push rod 208 for the helical coil spring type maximum rotation strength control mechanism of an integrated structure with the end face, and the push rod 208 for the helical coil spring type maximum rotation strength control mechanism runs through the helical coil spring type annular array A main hollow housing 201 for a maximum rotation strength control mechanism, which is located inside the main hollow section 202 for the helical spring array ring type maximum rotation strength control mechanism, wherein one end of a push rod 208 for the helical spring array ring type maximum rotation strength control mechanism, which is located inside the main hollow section 202 for the helical spring array ring type maximum rotation strength control mechanism, is of a semicircular structure, a semicircular groove structure 204 for the helical spring array ring type maximum rotation strength control mechanism, which is used for placing the end of the push rod 208 for the helical spring array ring type maximum rotation strength control mechanism, is provided on the side surface of a rotary column 203 for the helical spring array ring type maximum rotation strength control mechanism, and one end of the rotary column 203 for the helical spring ring array ring type maximum rotation strength control mechanism is fixed to the end of a main fourth rotary shaft 21; the initial length of the coil spring 207 for the maximum rotational strength control mechanism of the ring array coil spring type is longer than the length of the secondary hollow section 205 for the maximum rotational strength control mechanism of the ring array coil spring type; the structural shape of the end part of the push rod 208 for the annular array helical spring type maximum rotation strength control mechanism is consistent with the structural shape of the semicircular groove structure 204 for the annular array helical spring type maximum rotation strength control mechanism, and the structure has the main functions of: when the driving resistance is too large, the resistance is greater than the elasticity of the coil spring 207 for the maximum rotation strength control mechanism of the circular array coil spring type, so that the coil spring 207 for the maximum rotation strength control mechanism of the circular array coil spring type is compressed, and under the causal action, the two rotating shafts are relatively rotated to play a role in protection, so that the elasticity of the coil spring 207 for the maximum rotation strength control mechanism of the circular array coil spring type is smaller than the rotation force of the driving motor at the maximum power and smaller than the pressure strength when the surface of the lead is damaged.

Referring to fig. 4, the bevel gear set meshing type vertical angle connecting mechanism 24 includes a first bevel gear 241 for the bevel gear set meshing type vertical angle connecting mechanism, a shaft body mounting hole 242 for the bevel gear set meshing type vertical angle connecting mechanism, a second bevel gear 243 for the bevel gear set meshing type vertical angle connecting mechanism, and a central hole 244 for the bevel gear set meshing type vertical angle connecting mechanism; a shaft body mounting hole 242 for the meshing type vertical angle connecting mechanism of the bevel gear set is formed in the center of the bottom of the first bevel gear 241 for the meshing type vertical angle connecting mechanism of the bevel gear set, a second bevel gear 243 for the meshing type vertical angle connecting mechanism of the bevel gear set is bonded to the side surface of the first bevel gear 241 for the meshing type vertical angle connecting mechanism of the bevel gear set through a tooth structure, and a center hole 244 for the meshing type vertical angle connecting mechanism of the bevel gear set is formed in the center of the second bevel gear 243 for the meshing type vertical angle connecting mechanism of the bevel gear set; a main third rotating shaft 23 is arranged in a shaft body mounting hole 242 for the conical gear set meshing type vertical angle connecting mechanism; the meshing type vertical angle connecting mechanism of the bevel gear set is fixedly connected with the end part of the connecting pipeline body 10 by one end surface of a second bevel gear 243, and the main functions of the meshing type vertical angle connecting mechanism are as follows: the function of connecting rotation is achieved.

The specific use mode is as follows: during the operation of the invention, bare wires sequentially pass through the main through hole structure 5, the main second hollow structure 3, the main third hollow structure 4, the main first hollow structure 2 and the conical hollow structure 11, then the end part of the main first rotating shaft 16 is fixedly connected with the end part of the motor spindle of the driving motor, then water flow is injected into the device, the driving motor is started, the water flow is continuously sprayed out through the water flow spray nozzle 9 under the linkage action of the driving motor and the components, meanwhile, the inner annular shell 7 also can rotate rapidly, and at the moment, the wires pass through slowly.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The utility model provides a rivers encircle impacted style wire burring device, includes main body cover (1), its characterized in that: the water purifier is characterized in that a main first hollow structure (2) is arranged at the center of the upper end inside a main shell (1), a main second hollow structure (3) and a main third hollow structure (4) are respectively arranged on two sides of the main first hollow structure (2) inside the main shell (1), a main through hole structure (5) which is communicated with the outside and the main second hollow structure (3) and the main third hollow structure (4) is arranged inside the main shell (1), an annular mounting space (6) is arranged at the center of the inner wall of the main first hollow structure (2), an annular hollow shell (7) is mounted on the inner wall of the annular mounting space (6) through a main bearing and a sealing ring, a liquid reserved space (8) is arranged on the outer ring of the annular hollow shell (7), and a plurality of water flow nozzles (9) are mounted on the inner ring of the annular hollow shell (7), a connecting pipeline body (10) is installed at one end, facing a main first hollow structure (3), of the annular hollow shell (7), a conical hollow structure (11) is arranged inside one end of the connecting pipeline body (10), a main liquid drainage hole (12) communicated with a liquid reserved space (8) is formed in the bottom end of the main shell (1), a funnel-shaped structure (15) is arranged at the bottom of a main third hollow structure (4), a turbine installation space (13) is arranged at the bottom of the main liquid drainage hole (12), the center of the bottom of the internal turbine installation space (13) of the main shell (1) and a main liquid inlet hole (14) of the funnel-shaped structure (15) are arranged at one side of the turbine installation space (13), a main component installation space (17) is arranged at one side of the main component installation space (17), and a gear set meshed type rotation direction differentiation mechanism (18) is installed inside the main component installation space (17), two sides and the upper part of the gear set meshed type rotation direction differentiation mechanism (18) are respectively provided with a main first rotation shaft (16), a main second rotation shaft (19) and a main third rotation shaft (23), the top end of the main third rotation shaft (23) is meshed with the side surface of the connecting pipeline body (10) through a conical gear set meshed type vertical angle connecting mechanism (24), one end of the main second rotation shaft (19) is provided with an annular array spiral spring type maximum rotation strength control mechanism (20), the end center of the annular array spiral spring type maximum rotation strength control mechanism (20) is provided with a main fourth rotation shaft (21), and one end of the main fourth rotation shaft (21) positioned in the turbine installation space (13) is provided with a turbine (22).

2. The water current circumambient impact wire deburring apparatus of claim 1 wherein: the gear set meshed type rotation direction differentiation mechanism (18) comprises a hollow shell (181) for the gear set meshed type rotation direction differentiation mechanism, a connecting plate (182) for the gear set meshed type rotation direction differentiation mechanism, a bolt hole (183) for the gear set meshed type rotation direction differentiation mechanism, a hollow structure (184) for the gear set meshed type rotation direction differentiation mechanism, a first rotating shaft (185) for the gear set meshed type rotation direction differentiation mechanism, a first bearing (186) for the gear set meshed type rotation direction differentiation mechanism, a main gear (187) for the gear set meshed type rotation direction differentiation mechanism, a second rotating shaft (188) for the gear set meshed type rotation direction differentiation mechanism, a pinion (189) for the gear set meshed type rotation direction differentiation mechanism and a second bearing (1810) for the gear set meshed type rotation direction differentiation mechanism; a connecting plate (182) for the gear set meshed type rotating direction differentiation mechanism is mounted at the bottom of a hollow shell (181) for the gear set meshed type rotating direction differentiation mechanism, a plurality of bolt holes (183) for the gear set meshed type rotating direction differentiation mechanism are arranged inside the connecting plate (182) for the gear set meshed type rotating direction differentiation mechanism, a hollow structure (184) for the gear set meshed type rotating direction differentiation mechanism is arranged at the center inside the hollow shell (181) for the gear set meshed type rotating direction differentiation mechanism, a first rotating shaft (185) for the gear set meshed type rotating direction differentiation mechanism is mounted at the center of the bottom of the hollow shell (181) for the gear set meshed type rotating direction differentiation mechanism through a first bearing (186) for the gear set meshed type rotating direction differentiation mechanism at a penetrating part, and a gear set meshed type rotating direction differentiation mechanism is mounted at the top of the first rotating shaft (185) for the gear set meshed type rotating direction differentiation mechanism A first bearing (186) for a differentiating mechanism, a gear train meshing type main gear (187) for a rotating direction differentiating mechanism being attached to the tip end of the first rotating shaft (185) for a gear train meshing type rotating direction differentiating mechanism, the side surface of the hollow housing (181) for the gear-train meshing-type rotation direction differentiation mechanism is penetrated by a plurality of second rotating shafts (188) for the gear-train meshing-type rotation direction differentiation mechanism, and both are mounted at the penetration part by a gear set mesh type second bearing (1810) for the rotation direction differentiation mechanism, one end of each gear set mesh type second rotating shaft (188) for the rotation direction differentiation mechanism is provided with a gear set mesh type pinion (189) for the rotation direction differentiation mechanism, the pinion (189) for the gear set meshing type rotation direction differentiation mechanism is meshed with the main gear (187) for the gear set meshing type rotation direction differentiation mechanism through a tooth structure.

3. The water current circumambient impact wire deburring apparatus of claim 2 wherein: the outer ends of the second rotating shafts (188) for the two gear set meshing type rotating direction differentiating mechanisms are respectively connected with one ends of the main first rotating shaft (16) and the main second rotating shaft (19), and the end parts of the first rotating shafts (185) for the gear set meshing type rotating direction differentiating mechanisms are connected with the end parts of a main third rotating shaft (23).

4. The water current circumambient impact wire deburring apparatus of claim 2 wherein: the gear train meshing type connecting plate (182) for the rotation direction differentiation mechanism is mounted inside the main component mounting space (17) by bolts inserted into the gear train meshing type bolt holes (183) for the rotation direction differentiation mechanism.

5. The water current circumambient impact wire deburring apparatus of claim 1 wherein: the annular array helical spring type maximum rotation strength control mechanism (20) comprises a main hollow shell (201) for the annular array helical spring type maximum rotation strength control mechanism, a main hollow section (202) for the annular array helical spring type maximum rotation strength control mechanism, a rotary column (203) for the annular array helical spring type maximum rotation strength control mechanism, a semicircular groove structure (204) for the annular array helical spring type maximum rotation strength control mechanism, an auxiliary hollow section (205) for the annular array helical spring type maximum rotation strength control mechanism, a movable plate (206) for the annular array helical spring type maximum rotation strength control mechanism, a helical spring (207) for the annular array helical spring type maximum rotation strength control mechanism and a push rod (208) for the annular array helical spring type maximum rotation strength control mechanism; the center of one end face of a main hollow shell (201) for the annular array helical spring type maximum rotary strength control mechanism is fixedly connected with the end part of a main second rotating shaft (19), the center of the inside of the main hollow shell (201) for the annular array helical spring type maximum rotary strength control mechanism is a main hollow section (202) for the annular array helical spring type maximum rotary strength control mechanism, a rotary column (203) for the annular array helical spring type maximum rotary strength control mechanism is sleeved in the main hollow shell (201) for the annular array helical spring type maximum rotary strength control mechanism, the inside of the main hollow shell (201) for the annular array helical spring type maximum rotary strength control mechanism is an auxiliary hollow section (205) for the annular array helical spring type maximum rotary strength control mechanism, a movable plate (206) for the coil array type maximum rotary strength control mechanism is arranged in the auxiliary hollow section (205) for the coil array type maximum rotary strength control mechanism at one end face of the main hollow section (202) for the coil array type maximum rotary strength control mechanism, a coil spring (207) for the coil array type maximum rotary strength control mechanism is fixed between the auxiliary hollow section (205) for the coil array type maximum rotary strength control mechanism at one end of the movable plate (206) for the coil array type maximum rotary strength control mechanism, a push rod (208) for the coil array type maximum rotary strength control mechanism of an integrated structure with the movable plate (206) for the coil array type maximum rotary strength control mechanism is arranged at one end face of the movable plate (206) for the coil array type maximum rotary strength control mechanism, and the push rod (208) for the ring array coil spring type maximum rotary strength control mechanism penetrates through the main hollow shell (201) for the ring array coil spring type maximum rotary strength control mechanism and is positioned in the main hollow section (202) for the ring array coil spring type maximum rotary strength control mechanism, the push rod (208) for the ring array coil spring type maximum rotary strength control mechanism is in a semicircular structure at one end of the main hollow section (202) for the ring array coil spring type maximum rotary strength control mechanism, a semicircular groove structure (204) for the ring array coil spring type maximum rotary strength control mechanism, which is used for placing the end part of the push rod (208) for the ring array coil spring type maximum rotary strength control mechanism, is arranged on the side surface of the rotary column (203) for the ring array coil spring type maximum rotary strength control mechanism, one end of the rotary column (203) for the maximum rotary strength control mechanism of the ring array coil spring type is fixed to the end of the main fourth rotary shaft (21).

6. The water current circumambient impact wire deburring apparatus of claim 5 wherein: the initial length of the coil spring (207) for the maximum rotational strength control mechanism of the ring array coil spring type is longer than the length of the secondary hollow section (205) for the maximum rotational strength control mechanism of the ring array coil spring type.

7. The water current circumambient impact wire deburring apparatus of claim 5 wherein: the structural shape of the end part of the push rod (208) for the annular array helical spring type maximum rotary strength control mechanism is consistent with the structural shape of the semicircular groove structure (204) for the annular array helical spring type maximum rotary strength control mechanism.

8. The water current circumambient impact wire deburring apparatus of claim 1 wherein: the bevel gear set meshing type vertical angle connecting mechanism (24) comprises a first bevel gear (241) for the bevel gear set meshing type vertical angle connecting mechanism, a shaft body mounting hole (242) for the bevel gear set meshing type vertical angle connecting mechanism, a second bevel gear (243) for the bevel gear set meshing type vertical angle connecting mechanism and a central hole (244) for the bevel gear set meshing type vertical angle connecting mechanism; the bottom center of the first conical gear (241) for the conical gear set meshing type vertical angle connecting mechanism is provided with a shaft body mounting hole (242) for the conical gear set meshing type vertical angle connecting mechanism, the side surface of the first conical gear (241) for the conical gear set meshing type vertical angle connecting mechanism is meshed with a second conical gear (243) for the conical gear set meshing type vertical angle connecting mechanism through a tooth structure, and the center of the second conical gear (243) for the conical gear set meshing type vertical angle connecting mechanism is provided with a center hole (244) for the conical gear set meshing type vertical angle connecting mechanism.

9. The water current circumambient impact wire deburring apparatus of claim 8 wherein: and a main third rotating shaft (23) is arranged in a shaft body mounting hole (242) for the conical gear set meshing type vertical angle connecting mechanism.

10. The water current circumambient impact wire deburring apparatus of claim 8 wherein: the bevel gear set meshing type vertical angle connecting mechanism is fixedly connected with the end part of the connecting pipeline body (10) through one end surface of a second bevel gear (243).

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