CN220574606U - Reactor cutting equipment - Google Patents

Abstract

The utility model relates to the field of cutting equipment, in particular to reactor cutting equipment which comprises a bottom plate, a transverse clamping mechanism and a longitudinal clamping mechanism, wherein a sliding frame is movably arranged on the upper side of the rear end of the bottom plate. When the electric reactor winding cables with different sizes are required to be cut, the second motor is controlled to operate to drive the first screw head to rotate and mesh to drive the second screw head to rotate, the connected screw rod is driven to rotate and mesh to drive the sliding rod to move back and forth in the sliding groove or away from the sliding groove to adjust the front and back clamping distance, the telescopic rod is pulled upwards to enable the telescopic rod to move upwards in the telescopic groove to drive the side plate to extrude the hydraulic rod and the spring to generate potential energy, the height of the pressing plate is adjusted according to the thickness of the cut cable so as to enable the pressing plate to be correspondingly and firmly clamped and positioned, the first motor is controlled to operate to drive the cutter after the pressing plate is fixed, the front and back position of the cutter is adjusted under the pushing of the cylinder, and the transverse position of the cutter is adjusted under the driving of the driving component of the sliding frame, so that the winding cable of the electric reactor is efficiently and stably cut.

Description

Reactor cutting equipment

Technical Field

The utility model relates to the field of cutting equipment, in particular to reactor cutting equipment.

Background

The reactor is also called an inductor, and when one conductor is electrified, a magnetic field is generated in a certain space occupied by the conductor, so that all current-carrying electric conductors have common sense, and the reactors adopted in the power system are commonly provided with a series reactor and a parallel reactor. The series reactor is mainly used for limiting short-circuit current, and also is connected with a capacitor in series or in parallel in the filter for limiting higher harmonics in a power grid, an anti-blocking cable is required to be wound outside the reactor, and the cable is required to be cut according to the size before being used.

The existing cutting equipment has some defects: the existing cutting equipment positions the cut windings through manual twisting bolts, each positioning bolt needs to be twisted in the positioning process, the operation amount is increased, winding cables need to be produced in batches, positioning efficiency is affected, and the progress of the cutting process is affected.

Disclosure of Invention

The utility model aims to provide reactor cutting equipment, which is used for solving the problems that the existing cutting equipment positions a cut winding through manually twisting bolts, each positioning bolt needs to be twisted in the positioning process, the operation amount is increased, the positioning efficiency is influenced, and the progress of the cutting process is influenced.

Therefore, the utility model provides reactor cutting equipment, which comprises a bottom plate, a horizontal clamping mechanism and a vertical clamping mechanism, wherein a sliding frame is movably arranged on the upper side of the rear end of the bottom plate, an air cylinder is arranged at the front end of the sliding frame, a cutter is arranged at the lower end of the air cylinder through a connecting block, the left end of the cutter is connected with a first motor, the upper ends of two sides of the bottom plate are provided with the horizontal clamping mechanism for adjusting the front-rear distance of a clamping assembly, and the upper end of the horizontal clamping mechanism is provided with the vertical clamping mechanism for adjusting the height of the clamping assembly.

Preferably: the horizontal mechanism that presss from both sides includes the inside groove, the inside groove is transversely inside to be provided with first spiral shell head, first spiral shell head outer end is connected with the second motor, the second spiral shell head is installed to the inside groove front and back lateral wall, the spout has been seted up to the bottom plate upside of inside groove front and back direction, spout internally mounted has the screw rod of being connected with the second spiral shell head, screw rod outer wall cover is equipped with the slide bar.

Preferably: the longitudinal clamping mechanism comprises a telescopic groove, a telescopic rod is embedded in the telescopic groove, a side groove is formed in the side wall of the telescopic groove, a hydraulic rod is installed in the side groove, a spring is sleeved on the outer wall of the hydraulic rod, a side plate is installed on the side wall of the telescopic rod, and a pressing plate is installed at the upper end of the telescopic rod.

Preferably: the insection that first spiral shell head outer wall was equipped with and the insection intermeshing that second spiral shell head outer wall was equipped with.

Preferably: the cross section width of the sliding rod is matched with the cross section width of the sliding groove.

Preferably: the section size of the telescopic rod is matched with the section size of the telescopic groove.

Preferably: the upper end of the side plate is connected with one end of the spring, and the other end of the spring is fixedly connected with the side wall of the hydraulic rod.

When the electric reactor winding cables with different sizes are required to be cut, the second motor is controlled to operate to drive the first screw head to rotate and mesh to drive the second screw head to rotate, the connected screw rod is driven to rotate and mesh to drive the sliding rod to move back and forth in the sliding groove or away from the sliding groove to adjust the front and back clamping distance, the telescopic rod is pulled upwards to enable the telescopic rod to move upwards in the telescopic groove to drive the side plate to extrude the hydraulic rod and the spring to generate potential energy, the height of the pressing plate is adjusted according to the thickness of the cut cable so as to enable the pressing plate to be correspondingly and firmly clamped and positioned, the first motor is controlled to operate to drive the cutter after the pressing plate is fixed, the front and back positions of the cutter are adjusted under the pushing of the cylinder, and the transverse position of the cutter is adjusted under the driving of the driving component of the sliding frame, so that the winding cable of the electric reactor is efficiently and stably cut.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a top cross-sectional view of the cross-clamp mechanism of the present utility model;

fig. 3 is a side cross-sectional view of the longitudinal clamping mechanism of the present utility model.

In the figure:

1. a bottom plate; 2. a carriage; 3. a cylinder; 4. a cutter; 5. a first motor; 601. an inner tank; 602. a first screw head; 603. a second motor; 604. a second screw head; 605. a chute; 606. a screw; 607. a slide bar; 701. a telescopic slot; 702. a telescopic rod; 703. a side groove; 704. a side plate; 705. a hydraulic rod; 706. a spring; 707. and (5) pressing plates.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

Referring to fig. 1-3, a reactor cutting device according to a preferred embodiment of the present utility model includes a base plate 1, a horizontal clamping mechanism and a vertical clamping mechanism, a sliding frame 2 is movably mounted on an upper side of a rear end of the base plate 1, a cylinder 3 is mounted at a front end of the sliding frame 2, a cutter 4 is mounted at a lower end of the cylinder 3 through a connecting block, a first motor 5 is connected to a left end of the cutter 4, the horizontal clamping mechanism for adjusting a front-rear distance between two sides of the base plate 1 is disposed at upper ends of two sides of the base plate, and the vertical clamping mechanism for adjusting a height of a clamping assembly is disposed at an upper end of the horizontal clamping mechanism.

It should be noted that: in the scheme, the clamping efficiency of cutting the reactor component is improved through the transverse clamping mechanism and the longitudinal clamping mechanism.

The horizontal clamping mechanism comprises an inner groove 601, a first screw head 602 is arranged in the inner groove 601 in the horizontal direction, a second motor 603 is connected to the outer end of the first screw head 602, a second screw head 604 is arranged on the front side wall and the rear side wall of the inner groove 601, a sliding groove 605 is formed in the upper side of a bottom plate 1 in the front-rear direction of the inner groove 601, a screw 606 connected with the second screw head 604 is arranged in the sliding groove 605, and a sliding rod 607 is sleeved on the outer wall of the screw 606.

It should be noted that: this scheme is convenient for adjust clamping assembly front and back position.

Wherein, the insections on the outer wall of the first screw head 602 are engaged with the insections on the outer wall of the second screw head 604.

It should be noted that: this scheme is convenient for spacing around the efficient regulation.

The cross-sectional width of the sliding rod 607 is matched with the cross-sectional width of the sliding groove 605.

It should be noted that: this scheme makes centre gripping more stable around.

Example 2

Referring to fig. 1-3, the vertical clamping mechanism includes a telescopic slot 701, a telescopic rod 702 is embedded in the telescopic slot 701, a side slot 703 is provided on a side wall of the telescopic slot 701, a hydraulic rod 705 is installed in the side slot 703, a spring 706 is sleeved on an outer wall of the hydraulic rod 705, a side plate 704 is installed on a side wall of the telescopic rod 702, and a pressing plate 707 is installed at an upper end of the telescopic rod 702.

It should be noted that: this scheme is convenient for adjust vertical clamping assembly's interval.

Wherein, the cross section size of the telescopic rod 702 is matched with the cross section size of the telescopic groove 701.

It should be noted that: this scheme is convenient for stable regulation centre gripping.

The upper end of the side plate 704 is connected with one end of a spring 706, and the other end of the spring 706 is fixedly connected with the side wall of the hydraulic rod 705.

It should be noted that: this scheme is convenient for efficient regulation centre gripping.

The working flow and principle of the utility model are as follows: when the reactor winding cables with different sizes are required to be cut, the second motor 603 is controlled to operate to drive the first screw head 602 to rotate and mesh to drive the second screw head 604 to rotate, the connected screw rod 606 is driven to rotate and mesh to drive the sliding rod 607 to move back and forth in the sliding groove 605 to adjust the front-back clamping distance, the telescopic rod 702 is pulled upwards to enable the telescopic rod 702 to move upwards in the telescopic groove 701 to drive the side plate 704 to squeeze the hydraulic rod 705 and the spring 706 to generate potential energy, the height of the pressing plate 707 is adjusted according to the thickness of the cut cable so as to enable the corresponding firm clamping and positioning, the first motor 5 is controlled to operate to drive the cutter 4 after fixing, the front-back position of the cutter 4 is adjusted under the pushing of the cylinder 3, and the transverse position of the cutter 4 is adjusted under the driving of the driving component of the sliding frame 2.

The foregoing is a further elaboration of the present utility model in connection with the detailed description, and it is not intended that the utility model be limited to the specific embodiments shown, but rather that a number of simple deductions or substitutions be made by one of ordinary skill in the art without departing from the spirit of the utility model, should be considered as falling within the scope of the utility model as defined in the appended claims.

Claims (7)

1. A reactor cutting device is characterized in that: including bottom plate (1), horizontal clamp mechanism and indulge clamp mechanism, bottom plate (1) rear end upside movable mounting has carriage (2), cylinder (3) are installed to carriage (2) front end, cutter (4) are installed through linking the piece to cylinder (3) lower extreme, cutter (4) left end is connected with first motor (5), bottom plate (1) both sides upper end is provided with and is used for the horizontal clamp mechanism to centre gripping subassembly front and back interval adjustment, horizontal clamp mechanism upper end is provided with and is used for indulging clamp mechanism to centre gripping subassembly altitude mixture control.

2. A reactor trimming apparatus as defined in claim 1, wherein: the horizontal mechanism that presss from both sides includes inside groove (601), inside groove (601) transversely is inside to be provided with first spiral shell head (602), first spiral shell head (602) outer end is connected with second motor (603), second spiral shell head (604) are installed to lateral wall around inside groove (601), spout (605) have been seted up to bottom plate (1) upside of direction around inside groove (601), spout (605) internally mounted has screw rod (606) be connected with second spiral shell head (604), screw rod (606) outer wall cover is equipped with slide bar (607).

3. A reactor trimming apparatus as defined in claim 1, wherein: the vertical clamp mechanism comprises a telescopic groove (701), a telescopic rod (702) is embedded in the telescopic groove (701), a side groove (703) is formed in the side wall of the telescopic groove (701), a hydraulic rod (705) is arranged in the side groove (703), a spring (706) is sleeved on the outer wall of the hydraulic rod (705), a side plate (704) is arranged on the side wall of the telescopic rod (702), and a pressing plate (707) is arranged at the upper end of the telescopic rod (702).

4. A reactor trimming apparatus as defined in claim 2, wherein: the insections arranged on the outer wall of the first screw head (602) are meshed with insections arranged on the outer wall of the second screw head (604).

5. A reactor trimming apparatus as defined in claim 2, wherein: the cross-sectional width of the sliding rod (607) is matched with the cross-sectional width of the sliding groove (605).

6. A reactor trimming apparatus according to claim 3, wherein: the cross section size of the telescopic rod (702) is matched with the cross section size of the telescopic groove (701).

7. A reactor trimming apparatus according to claim 3, wherein: the upper end of the side plate (704) is connected with one end of a spring (706), and the other end of the spring (706) is fixedly connected with the side wall of the hydraulic rod (705).