CN113978902A - High-safety-performance bearing conveying device for mechanical equipment and using method thereof - Google Patents

Abstract

The invention provides a high-safety bearing transportation device for mechanical equipment and a using method thereof, relates to the technical field of bearing transportation, and solves the problems that the prior bearing transportation is difficult to simultaneously and effectively limit the outer ring and the inner ring of a bearing during the transportation of the bearing, thereby generating unnecessary abrasion due to the rotation of the bearing during the transportation, and is difficult to add rust preventive oil into the bearing during the transportation, thereby generating rust and abrasion, and the device comprises an auxiliary mechanism, wherein the main body of the auxiliary mechanism is designed into a cuboid structure, because the oil pumping assembly is arranged, the oil in the oil pumping assembly positioned at the inner side of a base plate flows onto a supporting assembly through an oil pipe arranged at the top end of the oil pumping assembly by extruding the base plate, and the bearing is coated through the rotation of the supporting assembly, thereby realizing the purpose of rust prevention.

Description

High-safety-performance bearing conveying device for mechanical equipment and using method thereof

Technical Field

The invention belongs to the technical field of bearing transportation, and particularly relates to a high-safety bearing transportation device for mechanical equipment and a using method thereof.

Background

The bearing is an important part in the modern mechanical equipment. Its main function is the support machinery rotator, reduces the coefficient of friction in its motion process to guarantee its gyration precision, because the bearing is the steel mostly, if receive the oxidation and exempt from to rust, must not damage the packing in handling, the bearing is in case rusty just influence the use. If the damaged package is needed to be checked, the bearing body is exposed or not, antirust oil is timely applied to replace the package, the bearing is not touched by naked hands, and the bearing is easy to rust.

For example, application No.: the invention discloses a carrier vehicle for bearing processing, which comprises a supporting transverse plate, wherein a supporting seat is fixedly connected to the top of the supporting transverse plate, a fixed block is fixedly connected to the top of the supporting seat, and an electric telescopic rod penetrates through the side face of the supporting seat. This transport vechicle is used in bearing processing, cup joint the bearing ring on the guide bar in proper order through the funnel, then drive the funnel through electric telescopic handle and change the guide bar and carry out the batch and put, it rotates to drive the rotation fluted disc through servo motor simultaneously, utilize the meshing of rotation fluted disc and driven fluted disc, it rotates to drive the dwang, utilize the screw thread displacement principle, drive the downward displacement of drive diaphragm through the thread bush, thereby make its guide bar displacement down, make its guide bar and the complete separation of the good bearing ring of arrangement, afterwards, through the removal of catch bar, make its catch bar push away to place on waiting to process the board with the good bearing of arrangement, thereby reached at the in-process of transportation, directly arrange the effect of putting in order to its bearing.

Based on the search of above-mentioned patent to and combine the equipment discovery among the prior art, above-mentioned equipment is when using, though can put in batches, but has had in the practical application in-process and has had firstly to be difficult to carry out the effective spacing simultaneously to the outer lane and the inner circle of bearing when transportation bearing, and then can produce unnecessary wearing and tearing because of the rotation of bearing in the transportation, secondly is difficult to add rust-preventive oil to the inside of bearing in the transportation, and then can have and produce rust stain and wearing and tearing.

Disclosure of Invention

In order to solve the technical problems, the invention provides a high-safety bearing transportation device for mechanical equipment and a use method thereof, and aims to solve the problems that in the actual application process of the existing bearing transportation, firstly, the outer ring and the inner ring of a bearing are difficult to be effectively limited simultaneously when the bearing is transported, unnecessary abrasion is generated due to the rotation of the bearing in transportation, and secondly, rust preventive oil is difficult to be added into the bearing in the transportation process, and rust and abrasion are generated.

The invention relates to a high-safety bearing transportation device for mechanical equipment and an application method thereof, and aims and effects of the transportation device are achieved by the following specific technical means:

a high-safety bearing transportation device for mechanical equipment and a using method thereof comprise an auxiliary mechanism,

the main part of the auxiliary mechanism is of a cuboid structural design, the left end inside the main part of the auxiliary mechanism is of an open right end closed structural design, a round hole with a round section is further formed in the main part of the auxiliary mechanism, and a limiting mechanism is further screwed in the round hole.

Further, stop gear includes:

the main body of the limiting frame is of a cuboid structure design with a hollow interior, the cross section of the limiting frame is of a rectangular structure design, the interior of the limiting frame is of a hollow structure design, square through grooves are formed in the top end and the bottom end of the limiting frame in a transverse array mode, a stud is further installed at the right end of the limiting frame and is screwed to the inner position of the bearing box through the stud;

further, the anti-injury mechanism comprises:

the main body of the substrate is designed into a cuboid structure, every two longitudinally adjacent substrates form a group, a transverse groove with a right side communicated in a one-way mode is formed in the substrate positioned on the upper side, and a round hole is formed in the substrate positioned on the lower side;

further, the support mechanism further includes:

the main body of the guide assembly is composed of a semicircular block and a triangular block, the guide assembly is rotatably connected to the front side of the combined assembly, the thickness of the guide assembly is consistent with that of the combined assembly, and the diameter of the guide assembly is smaller than the maximum distance between the guide columns;

the main body of the supporting component is a grooved wheel, the supporting component is arranged at the front side position of the combined component through two supporting rods and is linked through a guide pillar arranged at the front side of the combined component, and the slotting radian of the supporting component is matched with the outer side radian of the semicircular block in the guide component;

further, the assist mechanism includes:

the main body of the bearing box is in a cuboid structural design, a round hole is formed in the bearing box, the round hole and the main body of the bearing box are both in a left-end through right-end closed structural design, and the cross section of the bearing box is rectangular;

further, the anti-injury mechanism further comprises:

the main body of the oil pumping assembly is a container filled with lubricating oil, the container is of an extrusion structure, an elastic shrinkage column is further mounted at the bottom end of the oil pumping assembly, an oil delivery pipe is mounted at the top end of the oil pumping assembly, and the oil delivery pipe is normally located on the inner side of a combined assembly in the supporting mechanism;

further, the auxiliary mechanism further includes:

the main bodies of the clamping assemblies are designed to be semi-annular structures, the radian of the outer sides of the clamping assemblies is consistent with that of round holes formed in the bearing box, the outer sides of the two clamping assemblies are rotatably connected with screw rods, the tail ends of the screw rods are also provided with knobs which drive the screw rods to be meshed at the inner side positions of the bearing box, the semi-annular main bodies in the two clamping assemblies cannot form a whole circular ring when being contacted, and the inner sides of the clamping assemblies are also provided with limiting mechanisms;

further, the support mechanism includes:

the main body of the combined assembly is designed into a disc structure, a rotating shaft is arranged at the rear end of the combined assembly, guide pillars with the same size are arranged on the front end surface of the combined assembly in an annular array mode, and the distances among the guide pillars are different;

further, stop gear still includes:

the cross section of the main body of the limiting assembly is designed into a trapezoidal structure, every two longitudinally adjacent and reversely installed main bodies in the limiting assembly form a group, a square through groove is formed in each transverse member in the main body of the limiting assembly, and circular through holes are formed in the transverse members on the left side and the right side of each limiting assembly;

elastic component, elastic component's main part are the spring, and elastic component's inboard has still pegged graft the guide post to elastic component's diameter is greater than the diameter of guide post, the diameter of guide post and the inside round hole phase-match of seting up of spacing subassembly, and elastic component connects in the inboard position of every spacing subassembly of group, still installs in elastic component's inboard and prevents hindering the mechanism.

The invention discloses a use method of a high-safety bearing transportation device for mechanical equipment, which comprises the following steps:

1) firstly, sleeving an inner ring of a bearing on a limiting frame in a limiting mechanism, extruding a limiting component arranged on the inner side of the limiting frame through the inner ring of the bearing, and then sleeving the limiting component;

2) the sleeved bearing inner ring is supported by the limiting component, and the combined component in the supporting mechanism is continuously rotated after being supported to drive the supporting component to rotate through the guide component;

3) when the supporting component rotates, the oil pumping component in the injury prevention mechanism is pressed by the limit component to synchronously drive the base plate when moving inwards, and oil in the oil pumping component is dripped into the supporting component through the oil pumping pipe;

4) the supporting component holds up the inner ring of the bearing at the moment, oil is coated on the bearing, and the inner ring of the coated bearing is limited:

5) and then the limiting mechanism with the bearing is screwed to the inner position of the auxiliary mechanism through the stud, and then the outer ring of the bearing is clamped by manually rotating the clamping assembly.

Compared with the prior art, the invention has the following beneficial effects:

1. because the auxiliary mechanism is arranged, the screw rod in the clamping assembly can be twisted to enable the semi-ring clamping plates oppositely arranged at two positions to effectively limit and clamp the bearing outer ring borne by the limiting mechanism, and further the outer ring of the bearing is prevented from rotating in the transportation process.

2. Owing to be provided with stop gear, the edge of spacing subassembly is the arc structural design, consequently the accessible is spacing with the inner circle of bearing to the extrusion of spacing subassembly after the inner circle of bearing contacts with spacing subassembly, and the joint subassembly among the accessible rotation supporting mechanism drives two supporting component and props up the support to the inner circle of gear after spacing, and then has avoided the inner circle of bearing and spacing frame direct contact, has avoided the wearing and tearing that collide with in transit.

3. Owing to be provided with the oil pumping subassembly, through the base plate will be located the container main part's of the inboard oil pumping subassembly of base plate extrusion make inside fluid flow in on the supporting component through the oil pipe that its top was installed to rotate through the supporting component and paint the bearing, and then realize rust-resistant purpose.

Drawings

FIG. 1 is a schematic diagram of the right side view of the present invention in a half-section state.

Fig. 2 is a schematic front view of the present invention in a half-section state.

Fig. 3 is a schematic bottom side view of the present invention in a half-section configuration.

Fig. 4 is a left side view of the structure of the present invention in a half-section state.

Fig. 5 is a right side view of the assist mechanism of the present invention after removal.

Fig. 6 is an enlarged schematic view of the structure at a in fig. 1 according to the present invention.

Fig. 7 is an enlarged view of the structure of fig. 2 at B.

FIG. 8 is a schematic view of the assembly structure of the anti-injury mechanism and the supporting mechanism of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. an auxiliary mechanism; 101. a carrying case; 102. a clamping assembly; 2. a limiting mechanism; 201. a limiting frame; 202. a limiting component; 203. an elastic component; 3. a tamper-evident mechanism; 301. a substrate; 302. an oil pumping assembly; 4. a support mechanism; 401. a federation component; 402. a guiding component; 403. a support assembly.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a high-safety bearing transportation device for mechanical equipment and a using method thereof, wherein the transportation device comprises the following components: the auxiliary mechanism (1) is provided with a plurality of auxiliary mechanisms,

the main body of the auxiliary mechanism 1 is in a cuboid structural design, the left end inside the main body of the auxiliary mechanism 1 is in an open right end closed structural design, a round hole with a round section is further formed inside the main body of the auxiliary mechanism 1, and a limiting mechanism 2 is further screwed inside the round hole.

Wherein, the supporting mechanism 4 includes:

in the combined assembly 401, the main body of the combined assembly 401 is designed to be a disc structure, a rotating shaft is installed at the rear end of the combined assembly 401, guide pillars with the same size are installed on the front end surface of the combined assembly 401 in an annular array, and the distances between the guide pillars are different.

Wherein, stop gear 2 still includes:

the cross section of the main body of the limiting assembly 202 is designed to be a trapezoid structure, every two longitudinally adjacent and reversely installed main bodies in the limiting assembly 202 form a group, a square through groove is formed in each transverse member in the main body of each group of limiting assembly 202, and circular through holes are formed in the transverse members on the left side and the right side of each group of limiting assembly 202;

elastic component 203, elastic component 203's main part is the spring, and elastic component 203's inboard has still pegged graft and has had the guide post to elastic component 203's diameter is greater than the diameter of guide post, the diameter of guide post and the inside round hole phase-match that offers of spacing subassembly 202, and elastic component 203 connects in the inboard position of every group spacing subassembly 202, still installs in elastic component 203's inboard and prevents hindering mechanism 3.

Wherein, stop gear 2 includes:

spacing 201, the main part of spacing 201 is inside hollow cuboid structural design, and the cross-section of spacing 201 is rectangle structural design to spacing 201's inside is hollow structural design, all is horizontal array at spacing 201's top and bottom and has seted up square logical groove, still installs the double-screw bolt at spacing 201's right-hand member, and connects the internal position at bearing box 101 through the double-screw bolt twist.

Wherein, supporting mechanism 4 still includes:

the main body of the guide component 402 is composed of a semicircular block and a triangular block, the guide component 402 is rotatably connected to the front side of the combined component 401, the thickness of the guide component 402 is consistent with that of the combined component 401, but the diameter of the guide component 402 is smaller than the maximum distance between the guide columns;

the main body of the supporting component 403 is a grooved wheel, the supporting component 403 is mounted at the front side of the joint component 401 through two supporting rods, and is linked through a guide post mounted at the front side of the joint component 401, and the slotting radian of the supporting component 403 is matched with the outer side radian of the semicircular block in the guide component 402.

Wherein, complementary unit 1 includes:

bearing box 101, bearing box 101's main part is cuboid structural design, and has seted up the round hole in bearing box 101's inside, and the round hole is the left end for being with bearing box 101's main part and link up right-hand member closed structure design, and bearing box 101's cross-section is the rectangle.

Wherein, complementary unit 1 still includes:

clamping component 102, clamping component 102's main part is the design of half ring configuration, and clamping component 102's outside radian is unanimous with the radian of the inside round hole of seting up of bearing box 101, the outside of two clamping component 102 all rotates and is connected with the screw rod, end at the screw rod still is equipped with the knob, and drive the inboard position of screw rod meshing at bearing box 101 through the knob, and can not constitute a complete ring when the half ring main part in two clamping component 102 contacts, stop gear 2 is still installed to inboard at clamping component 102.

Wherein, prevent hindering mechanism 3 still includes:

the main body of the oil pumping assembly 302 is a container filled with lubricating oil, the container is of an extrusion structure, an elastic shrinkage column is further mounted at the bottom end of the oil pumping assembly 302, an oil delivery pipe is mounted at the top end of the oil pumping assembly 302, and the oil delivery pipe is located on the inner side of a combined assembly 401 in the supporting mechanism 4 in a normal state.

Wherein, prevent hindering mechanism 3 includes:

the base plate 301, the main part of base plate 301 is cuboid structural design, and wherein every two vertically adjacent base plates 301 be a set of, and wherein the horizontal groove that the right side one-way link up is seted up to the inside of the base plate 301 that is located the upside, and the round hole has been seted up to the inside of the base plate 301 that is located the downside.

The invention discloses a use method of a high-safety bearing transportation device for mechanical equipment, which comprises the following steps:

1) firstly, sleeving an inner ring of a bearing on a limiting frame 201 in a limiting mechanism 2, extruding a limiting component 202 arranged on the inner side of the limiting frame 201 through the inner ring of the bearing, and then sleeving the limiting component;

2) the sleeved bearing inner ring is supported by the limiting component 202, and the combined component 401 in the supporting mechanism 4 is continuously rotated after being supported to drive the supporting component 403 to rotate through the guide component 402;

3) when the supporting component 403 rotates, because the oil pumping component 302 in the anti-injury mechanism 3 is subjected to the pressure of the substrate 301 synchronously driven when the limiting component 202 moves inwards, oil in the oil pumping component 302 is dripped into the supporting component 403 through the oil pumping pipe;

4) supporting component 403 holds up the bearing inner ring this moment to scribble oil and establish to the bearing on, scribble the inner ring of establishing the bearing that finishes and promptly by spacingly:

5) and then screwing the limiting mechanism 2 loaded with the bearing to the inner position of the auxiliary mechanism 1 through a stud, and then clamping the outer ring of the bearing by manually rotating the clamping assembly 102.

When in use: because the main body of the bearing box 101 in the auxiliary mechanism 1 is designed into a cuboid structure, a round hole is formed in the bearing box 101, the round hole and the main body of the bearing box 101 are both designed into a structure with a left end communicated and a right end closed, the cross section of the bearing box 101 is rectangular, the limiting mechanism 2 can be screwed and assembled in the bearing box 101 through bolts, and after the assembly is completed, two semi-ring clamping plates oppositely arranged are used for effectively limiting and clamping the outer ring of the bearing borne in the limiting mechanism 2 by twisting a screw rod in the clamping assembly 102, so that the outer ring of the bearing is prevented from rotating in the transportation process;

on the other hand, when the bearing is assembled above the limiting frame 201 in the limiting mechanism 2, the bearing is firstly contacted with the limiting component 202 which is arranged on the inner side of the limiting frame 201 through the elastic component 203, and the edges of the limiting component 202 are both designed in an arc structure, so that the inner ring of the bearing can be limited by extruding the limiting component 202 after the inner ring of the bearing is contacted with the limiting component 202, and the inner ring of the gear can be supported and supported by driving the two supporting components 403 through the combined component 401 in the rotating supporting mechanism 4 after the limiting, so that the inner ring of the bearing is prevented from being directly contacted with the limiting frame 201, and the collision and abrasion in the transportation process are avoided;

furthermore, when the limiting assembly 202 is pressed inward by a force, the base plate 301 is synchronously driven to close inward, the oil inside the oil pumping assembly 302 in the base plate 301 flows into the supporting assembly 403 through the oil pipe arranged at the top end of the oil pumping assembly by the extrusion of the base plate 301, and the bearing is coated by the rotation of the supporting assembly 403, so that the purpose of rust prevention is achieved.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. The utility model provides a high security performance bearing conveyer for mechanical equipment and application method thereof which characterized in that: bearing conveyer, including complementary unit, complementary unit's main part is cuboid structural design, and is opening right-hand member enclosed construction design at complementary unit's the inside left end of main part, still sets up the cross-section in complementary unit's main part inside and be circular shape round hole, still twists in the inside of round hole and connect limiting mechanism.

2. A high-safety bearing transportation apparatus for mechanical equipment according to claim 1, wherein: the assist mechanism includes:

the bearing box is characterized in that the main body of the bearing box is in a cuboid structural design, round holes are formed in the bearing box, the round holes are in a left-end through right-end closed structural design with the main body of the bearing box, and the cross section of the bearing box is rectangular.

3. A high-safety bearing transportation apparatus for mechanical equipment according to claim 2, wherein: the assist mechanism further includes:

clamping component, clamping component's main part is the design of half ring structure, and clamping component's outside radian is unanimous with the radian of the inside round hole of seting up of bearing box, and two clamping component's the outside is all rotated and is connected with the screw rod, still is equipped with the knob at the end of screw rod to drive the screw rod meshing through the knob and put at the inboard of bearing box, and can not constitute a whole ring when the half ring shape main part in two clamping component contacts, stop gear is still installed in clamping component's inboard.

4. A high-safety bearing transportation apparatus for mechanical equipment according to claim 3, wherein: the stop gear includes:

spacing, spacing main part are inside hollow cuboid structural design, and spacing cross-section is rectangle structural design to spacing inside is hollow structural design, all is horizontal array at spacing top and bottom and has seted up square logical groove, still installs the double-screw bolt at spacing right-hand member, and connects the internal position at the bearing box through the double-screw bolt is twisted.

5. The high-safety bearing transportation device for mechanical equipment according to claim 4, wherein: stop gear still includes:

the cross section of the main body of the limiting assembly is designed into a trapezoidal structure, every two longitudinally adjacent and reversely installed main bodies in the limiting assembly form a group, a square through groove is formed in each transverse member in the main body of the limiting assembly, and circular through holes are formed in the transverse members on the left side and the right side of each limiting assembly;

elastic component, elastic component's main part are the spring, and elastic component's inboard has still pegged graft the guide post to elastic component's diameter is greater than the diameter of guide post, the diameter of guide post and the inside round hole phase-match of seting up of spacing subassembly, and elastic component connects in the inboard position of every spacing subassembly of group, still installs in elastic component's inboard and prevents hindering the mechanism.

6. The high-safety bearing transportation device for mechanical equipment according to claim 5, wherein: the injury prevention mechanism comprises:

the base plate, the main part of base plate is cuboid structural design, and wherein every two vertically adjacent base plates of department are a set of, and wherein the horizontal groove that the right side one-way link up is seted up to the inside of the base plate that is located the upside, and the round hole has been seted up to the inside of the base plate that is located the downside.

7. The high-safety bearing transportation device for mechanical equipment according to claim 6, wherein: the anti-injury mechanism further comprises:

the main part of the oil pumping assembly is a container filled with lubricating oil, the container is of an extrusion structure, an elastic shrinkage column is further mounted at the bottom end of the oil pumping assembly, an oil delivery pipe is mounted at the top end of the oil pumping assembly, and the oil delivery pipe is located on the inner side of a combined assembly in the supporting mechanism in a normal state.

8. A high-safety bearing transportation apparatus for mechanical equipment according to claim 7, wherein: the support mechanism includes:

the main body of the combined assembly is designed into a disc structure, a rotating shaft is installed at the rear end of the combined assembly, guide columns with the same size are installed on the front end face of the combined assembly in an annular array mode, and the distances among the guide columns are different.

9. A high-safety bearing transportation apparatus for mechanical equipment according to claim 8, wherein: the support mechanism further includes:

the main body of the guide assembly is composed of a semicircular block and a triangular block, the guide assembly is rotatably connected to the front side of the combined assembly, the thickness of the guide assembly is consistent with that of the combined assembly, and the diameter of the guide assembly is smaller than the maximum distance between the guide columns;

the supporting component is provided with a grooved wheel, the supporting component is arranged at the front side of the combined component through two supporting rods and is linked through a guide pillar arranged at the front side of the combined component, and the grooving radian of the supporting component is matched with the outer side radian of the semicircular block in the guide component.

10. A method of using a high safety bearing transportation device for mechanical equipment according to claims 1-9, wherein: the method comprises the following steps:

1) firstly, sleeving an inner ring of a bearing on a limiting frame in a limiting mechanism, extruding a limiting component arranged on the inner side of the limiting frame through the inner ring of the bearing, and then sleeving the limiting component;

2) the sleeved bearing inner ring is supported by the limiting component, and the combined component in the supporting mechanism is continuously rotated after being supported to drive the supporting component to rotate through the guide component;

3) when the supporting component rotates, the oil pumping component in the injury prevention mechanism is pressed by the limit component to synchronously drive the base plate when moving inwards, and oil in the oil pumping component is dripped into the supporting component through the oil pumping pipe;

4) the supporting component holds up the inner ring of the bearing at the moment, oil is coated on the bearing, and the inner ring of the coated bearing is limited:

5) and then the limiting mechanism with the bearing is screwed to the inner position of the auxiliary mechanism through the stud, and then the outer ring of the bearing is clamped by manually rotating the clamping assembly.

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