CN117486025A - Electrical debugging device for simulated elevator - Google Patents

Abstract

The invention discloses an electric debugging device for a simulated elevator, which structurally comprises a control box, a motor box, guide rods, an elevator box, cable rods, a supporting plate and a connecting plate, wherein the control box is arranged at the upper end of the supporting plate, the motor box is embedded and fixed at the upper end of the supporting plate, the control box is connected with a circuit of the motor box, the guide rods are arranged on the side face of the supporting plate, the cable rods are embedded and fixed at the inner side of the motor box, the connecting plate is welded at the upper end of the elevator box, and the elevator box is positioned below the supporting plate.

Description

Electrical debugging device for simulated elevator

Technical Field

The invention relates to the technical field of simulated elevator debugging devices, in particular to an electric debugging device for a simulated elevator.

Background

The elevator simulation electric appliance debugging device can better know the operation principle of an elevator, collect the operation data of the elevator through the operation of the elevator simulation, so that the elevator can be intuitively known, the smoothness of a circuit is required to be ensured before the elevator is debugged, sundries on devices such as a well, a pit, a car and the like are required to be cleaned, and the elevator is not disturbed in the debugging process.

But the cable stretches from top to bottom in the debugging process, the round bar of ware guide guides the removal of cable, the cable guide can form the angle, guide the cable on a groove, along with the rolling of cable coil when the cable moves, the cable rubs with round bar side easily, and then the resistance to the cable is relatively poor, easily to cable tensile friction, the stability of cable when influencing the debugging, and the elevator box has certain weight, when the height overlength of lift, need keep the elevator box acceleration unchanged, but the greater the lift height the inertia that the elevator box goes up and down can be greater, thereby the acceleration of elevator box slightly changes easily, cause the condition that the elevator box rocked easily.

Disclosure of Invention

The technical scheme adopted for realizing the technical purpose of the invention is as follows: the utility model provides an electric debugging device of simulation elevator, its structure includes control box, motor case, guide bar, elevator case, cable pole, backup pad, connecting plate, the control box is installed in the backup pad upper end, the motor case is inlayed and is fixed in the backup pad upper end, control box and motor case line connection, the guide bar is installed in the backup pad side, the cable pole is inlayed and is fixed in the motor case inboard, the connecting plate welding is in the elevator case upper end, the elevator case is located the backup pad below, the guide bar is equipped with bracing piece, movable rod, first bearing ring, sliding plate, the bracing piece is inlayed and is fixed in first bearing ring inboard, first bearing ring is installed in the movable rod side, sliding plate sliding fit in the movable rod, the bracing piece is located same central axis with the movable rod, the bracing piece is installed in the backup pad side, be equipped with three sliding plate on the movable rod, evenly arranged distributes, and the cable on sliding plate and the cable pole corresponds each other.

As a further improvement of the invention, the sliding plate is provided with a second bearing ring, a limiting plate and a rotating ring, the second bearing ring is clamped on the inner side of the rotating ring, the limiting plate is arranged on the inner side of the second bearing ring, the rotating ring is in sliding fit in the movable rod, and the side surface of the rotating ring is provided with a ball which slides on the inner side of the movable rod.

As a further improvement of the invention, the limiting plate is provided with a stress ring, a metal pipe, a bearing plate and a connecting rod, wherein the stress ring is arranged on the outer side of the metal pipe, the metal pipe is embedded and fixed on the inner side of the bearing plate, the outer side of the bearing plate is arranged on the inner side of the second bearing ring, the connecting rod penetrates through the inner part of the metal pipe and is welded with the supporting rod, and the stress ring is in a state that two sides of the stress ring are inclined inwards by 30 degrees, so that the effect of centralizing stress points is achieved.

As a further improvement of the invention, the stress ring is provided with an inclined plate, a bending plate and a rubber plate, the bending plate is embedded and fixed on the inner side of the rubber plate, the rubber plate is clamped in the middle position of the inclined plate, the inclined plate is arranged on the outer side of the metal pipe, gaps are arranged on the left side and the right side of the bending plate, and the cable is positioned on the surface position of the bending plate.

As a further improvement of the invention, the elevator box is provided with rectangular plates, baffle plates, sliding rods and a movable box, wherein the rectangular plates are in sliding fit with the top corners of the movable box, the sliding rods are arranged on the outer sides of the movable box, the sliding rods are in sliding fit with the baffle plates, the connecting plates are welded on the top ends of the movable box, the number of the rectangular plates is four, the square state distribution is realized, the number of the sliding rods is four, the sliding rods are distributed on the left side and the right side of the movable box, and the rectangular plates and the baffle plates are in a fixed state.

As a further improvement of the invention, the blocking plate is provided with spring rods, stress plates and fixing plates, the spring rods are embedded and fixed on the outer sides of the stress plates, the spring rods are arranged on the inner sides of the fixing plates, the stress plates are in sliding fit with the sliding rods, the outer sides of the stress plates are in an arc-shaped state, the friction force is small, and the four stress plates are horizontally and symmetrically distributed on the inner sides of the fixing plates.

Advantageous effects

1. According to the invention, the cable is wound and unwound through the guide of the guide rod, the cable is connected to the connecting plate to lift the elevator box, the lift is debugged, the cable slides on the sliding plate, the movable rod is connected to the outer side of the supporting rod through the first bearing ring to rotate, the elevator box is lifted after the cable is guided, various data such as lifting speed, resistance acceleration and the like are collected into the control box, and the rationality of the data is debugged.

2. According to the invention, the cables are clamped on two sides of the stress ring, and a holding force is generated on the bending plate under the clearance of the bending plate when the cables move, so that the bending plate is driven by the cables to be extruded and bent towards the rubber plate, the attaching rotating force of the whole inclined plate to the cables is enhanced, friction is prevented when the cables are guided, the stabilizing force of the cables during guiding can be enhanced, the cables are prevented from being stressed unevenly and sliding left and right on the stress ring, the rotating force generated by the movement of the cables drives the second bearing ring on the inner side of the rotating ring to rotate, and the rotating resistance of the cable guiding is reduced through repeated transmission rotation, so that the friction resistance generated by the cable guiding is prevented from being insufficiently smooth and the stability is prevented from being damaged.

3. According to the invention, the cable lifts the elevator box, the sliding rod and the right angle plate respectively guide the sliding rod and the movable box to slide, when the lifting height of the movable box is overlarge, the inertia of the movable box can slightly shake, the stress plate extrudes the spring rod, the movable box keeps acceleration not disturbed by the inertia under the support of the fixed plate, shaking force generated by the change of the lifting acceleration is blocked, and the overlarge and unstable lifting height is avoided.

Drawings

Fig. 1 is a schematic structural diagram of an electric debugging device for an analog elevator according to the present invention.

Fig. 2 is a schematic perspective view of a guide bar according to the present invention.

Fig. 3 is a schematic plan view of a sliding plate according to the present invention.

Fig. 4 is a schematic side view of a limiting plate according to the present invention.

Fig. 5 is a schematic perspective view of a stress ring according to the present invention.

Fig. 6 is a schematic top view of an elevator car of the present invention.

Fig. 7 is a schematic plan view of a blocking plate according to the present invention.

In the figure: control box-1, motor box-2, guide bar-3, elevator box-4, cable bar-5, support plate-6, connecting plate-7, support bar-31, movable bar-32, first bearing ring-33, sliding plate-34, second bearing ring-w 1, limit plate-w 2, rotating ring-w 3, stress ring-w 21, metal tube-w 22, bearing plate-w 23, connecting bar-w 24, inclined plate-e 1, curved plate-e 2, rubber plate-e 3, right angle plate-t 1, blocking plate-t 2, sliding bar-t 3, movable box-t 4, spring bar-t 21, stress plate-t 22, and fixed plate-t 23.

Description of the embodiments

The invention is further described below with reference to the accompanying drawings:

examples

As shown in fig. 1 to 5:

the invention relates to an electric debugging device for an analog elevator, which structurally comprises a control box 1, a motor box 2, a guide rod 3, an elevator box 4, a cable rod 5, a support plate 6 and a connecting plate 7, wherein the control box 1 is arranged at the upper end of the support plate 6, the motor box 2 is embedded and fixed at the upper end of the support plate 6, the control box 1 is connected with the motor box 2 in a circuit manner, the guide rod 3 is arranged at the side surface of the support plate 6, the cable rod 5 is embedded and fixed at the inner side of the motor box 2, the connecting plate 7 is welded at the upper end of the elevator box 4, the elevator box 4 is positioned below the support plate 6, the guide rod 3 is provided with a support rod 31, a movable rod 32, a first bearing ring 33 and a sliding plate 34, the support rod 31 is embedded and fixed at the inner side of the first bearing ring 33, the first bearing ring 33 is arranged at the side surface of the movable rod 32, the sliding plate 34 is in sliding fit with the movable rod 32, the support rod 31 and the movable rod 32 are arranged at the side surface of the support plate 6 in a circuit manner, three sliding plates 34 are uniformly distributed on the movable rod 32, the sliding plate 34 is arranged on the cable rod 2, the sliding plate is in a sliding plate 34 is arranged on the sliding plate 3, and the sliding plate is in a sliding plate 34 sliding plate 3 sliding plate is further connected with the sliding plate 3, and the sliding plate 3, when the cable rod is in a sliding plate 3, and the sliding plate 3 is in a sliding plate 3 sliding plate, and the sliding plate is in a sliding plate 3, and a sliding plate is in a sliding plate.

The sliding plate 34 is provided with a second bearing ring w1, a limiting plate w2 and a rotating ring w3, the second bearing ring w1 is clamped inside the rotating ring w3, the limiting plate w2 is mounted inside the second bearing ring w1, the rotating ring w3 is slidably matched with the movable rod 32, a ball is arranged on the side surface of the rotating ring w3 and slides inside the movable rod 32, so that the limiting plate w2 rotates on the second bearing ring w1 inside the rotating ring w3 after receiving the sliding force of the cable, and meanwhile the rotating ring w3 rotates under the support of the movable rod 32 and is transmitted and rotated for multiple times, so that the rotation resistance guided by the cable is reduced and the cable friction is prevented.

The limiting plate w2 is provided with a stress ring w21, a metal tube w22, a stress bearing plate w23 and a connecting rod w24, the stress ring w21 is installed on the outer side of the metal tube w22, the metal tube w22 is embedded and fixed on the inner side of the stress bearing plate w23, the outer side of the stress bearing plate w23 is installed on the inner side of the second bearing ring w1, the connecting rod w24 penetrates through the inner side of the metal tube w22 and is welded with the supporting rod 31, the stress ring w21 is in a state that two sides are inclined inwards by 30 degrees, the effect that stress points are concentrated is achieved, cables are clamped on two sides of the stress ring w21, the stress points of the cables are distributed on the left side and the right side, the cables are driven to rotate when being wound and unwound on the stress ring w21, the stress bearing plate w23 rotates on the inner side of the second bearing ring w1, and the stabilizing force of the cables during guiding can be enhanced, and the cables are prevented from being stressed unevenly and sliding left and right on the stress ring w 21.

The stress ring w21 is provided with an inclined plate e1, a bent plate e2 and a rubber plate e3, the bent plate e2 is fixedly embedded in the inner side of the rubber plate e3, the rubber plate e3 is clamped at the middle position of the inclined plate e1, the inclined plate e1 is installed on the outer side of the metal tube w22, gaps are formed in the left side and the right side of the bent plate e2, a cable is located at the surface position of the bent plate e2, and therefore grabbing force is generated on the bent plate e2 under the gap of the bent plate e2 when the cable moves, the cable drives the bent plate e2 to extrude and bend towards the rubber plate e3, the attaching rotating force of the whole inclined plate e1 to the cable is enhanced, and friction is prevented when the cable is guided.

Specific use and action of the embodiment:

in the invention, a motor case 2 drives a cable rod 5 to rotate under the control of a control case 1, so that cables are wound and unwound through the guidance of a guide rod 3, the cables are connected to a connecting plate 7 to lift an elevator case 4, the lifting is regulated, the guide rod 3 generates supporting force when the cables are guided, the cables slide on a sliding plate 34, a movable rod 32 is connected to the outer side of a supporting rod 31 through a first bearing ring 33 to rotate, the elevator case 4 is lifted after the cables are guided, and various data such as lifting speed, resistance acceleration and the like are summarized into the control case 1, and the rationality of the data is regulated.

In the invention, after the limiting plate w2 in the sliding plate 34 receives the sliding force of the cable, the cable is clamped on two sides of the bearing ring w21, when the cable moves, a holding force is generated on the bending plate e2 under the clearance of the bending plate e2, and then the cable drives the bending plate e2 to press and bend towards the rubber plate e3, so that the whole pasting rotating force of the inclined plate e1 on the cable is enhanced, friction is prevented when the cable is guided, the bearing points of the cable are distributed on the left side and the right side of the bearing ring w21, the metal tube w22 is driven to rotate when the cable is wound and unwound, the bearing plate w23 rotates on the inner side of the second bearing ring w1, the stabilizing force of the cable during guiding can be enhanced, the cable is prevented from sliding on the left side and right side of the bearing ring w21 due to uneven bearing force, and then the rotating force generated by the cable movement drives the second bearing ring w1 on the inner side of the rotating ring w3 to rotate under the support of the movable rod 32, and the rotating resistance generated by multiple transmission rotation is reduced, so that the cable guiding is prevented from generating friction resistance due to uneven guiding and stability is damaged.

Examples

As shown in fig. 6 to 7:

the elevator car 4 is provided with a right angle plate t1, a blocking plate t2, a sliding rod t3 and a movable box t4, wherein the right angle plate t1 is in sliding fit with the top angle of the movable box t4, the sliding rod t3 is arranged on the outer side of the movable box t4, the sliding rod t3 is in sliding fit with the blocking plate t2, the connecting plate 7 is welded at the top end of the movable box t4, the right angle plate t1 is provided with four square-shaped state distribution, the sliding rod t3 is provided with four square-shaped state distribution, the square-shaped state distribution is distributed on the left side and the right side of the movable box t4, the right angle plate t1 and the blocking plate t2 are in fixed states, so that the movable box t4 is lifted by a cable under the connection of the connecting plate 7, the sliding rod t3 and the right angle plate t1 respectively guide the sliding rod t3 and the movable box t4, the movable state of lifting of the movable box t4 is limited, and the movable state of the movable box t4 is prevented from swinging when the movable box t4 is lifted.

The blocking plate t2 is provided with a spring rod t21, a stress plate t22 and a fixed plate t23, the spring rod t21 is fixedly embedded on the outer side of the stress plate t22, the spring rod t21 is installed on the inner side of the fixed plate t23, the stress plate t22 is in sliding fit with the sliding rod t3, the outer side of the stress plate t22 is in an arc-shaped state and has the characteristic of small friction force, the stress plate t22 is provided with four horizontally symmetrical distribution on the inner side of the fixed plate t23, when the lifting height of the movable box t4 is overlarge, the inertia of the movable box t4 can slightly shake, the stress plate t22 extrudes the spring rod t21, the movable box t4 is kept to be lifted in a sliding mode on the inner side of the fixed plate t23 under the support of the fixed plate t23, the movable box t4 is kept from being accelerated to be disturbed by inertia, shaking power generated by the change of the lifting acceleration is prevented, and the lifting height is prevented from being overlarge and unstable.

Specific use and action of the embodiment:

according to the invention, a movable box t4 in an elevator box 4 is lifted by a cable under the connection of a connecting plate 7, a sliding rod t3 and a right angle plate t1 respectively guide the sliding rod t3 and the movable box t4 to slide, a movable lifting state of the movable box t4 is limited, when the lifting height of the movable box t4 is overlarge, inertia of the movable box t4 can slightly shake, a stress plate t22 presses a spring rod t21, the movable box t4 is kept to slide and lift on the inner side of the fixed plate t23 under the support of a fixed plate t23, acceleration of the movable box t4 is kept not disturbed by inertia, shaking force generated by the change of the lifting acceleration is blocked, and the lifting height is prevented from being overlarge and unstable.

By utilizing the technical scheme of the invention or under the inspired by the technical scheme of the invention, a similar technical scheme is designed by a person skilled in the art, so that the technical effects are achieved, and the technical scheme falls into the protection scope of the invention.

Claims (6)

1. The utility model provides an electric debugging device of simulation elevator, its structure includes control box (1), motor case (2), guide bar (3), elevator box (4), hawser pole (5), backup pad (6), connecting plate (7), its characterized in that: the control box (1) is arranged at the upper end of the supporting plate (6), the motor box (2) is embedded at the upper end of the supporting plate (6), the control box (1) is connected with the motor box (2) in a circuit manner, the guide rod (3) is arranged on the side surface of the supporting plate (6), the cable rod (5) is embedded at the inner side of the motor box (2), the connecting plate (7) is welded at the upper end of the elevator box (4), and the elevator box (4) is positioned below the supporting plate (6);

the guide rod (3) is provided with a support rod (31), a movable rod (32), a first bearing ring (33) and a sliding plate (34), wherein the support rod (31) is embedded and fixed on the inner side of the first bearing ring (33), the first bearing ring (33) is installed on the side face of the movable rod (32), the sliding plate (34) is in sliding fit with the movable rod (32), the support rod (31) and the movable rod (32) are located on the same central axis, and the support rod (31) is installed on the side face of the support plate (6).

2. The simulated elevator electrical commissioning device of claim 1, wherein: the sliding plate (34) is provided with a second bearing ring (w 1), a limiting plate (w 2) and a rotating ring (w 3), the second bearing ring (w 1) is clamped on the inner side of the rotating ring (w 3), the limiting plate (w 2) is arranged on the inner side of the second bearing ring (w 1), and the rotating ring (w 3) is in sliding fit in the movable rod (32).

3. The simulated elevator electrical debugging device of claim 2, wherein: limiting plate (w 2) are equipped with atress ring (w 21), tubular metal resonator (w 22), load-bearing plate (w 23), connecting rod (w 24), atress ring (w 21) are installed in tubular metal resonator (w 22) outside, tubular metal resonator (w 22) are inlayed and are solid in load-bearing plate (w 23) inboard, load-bearing plate (w 23) outside is installed in second bearing ring (w 1) inboard, connecting rod (w 24) run through inside tubular metal resonator (w 22), and weld mutually with bracing piece (31).

4. A simulated elevator electrical commissioning device as claimed in claim 3, wherein: the stress ring (w 21) is provided with an inclined plate (e 1), a bending plate (e 2) and a rubber plate (e 3), the bending plate (e 2) is embedded and fixed on the inner side of the rubber plate (e 3), the rubber plate (e 3) is clamped at the middle position of the inclined plate (e 1), and the inclined plate (e 1) is mounted on the outer side of the metal tube (w 22).

5. The simulated elevator electrical commissioning device of claim 1, wherein: the elevator car (4) is provided with a right angle plate (t 1), a blocking plate (t 2), a sliding rod (t 3) and a movable box (t 4), wherein the right angle plate (t 1) is in sliding fit with the top angle of the movable box (t 4), the sliding rod (t 3) is arranged on the outer side of the movable box (t 4), the sliding rod (t 3) is in sliding fit with the blocking plate (t 2), and the connecting plate (7) is welded on the top end of the movable box (t 4).

6. The simulated elevator electrical commissioning device of claim 5, wherein: the blocking plate (t 2) is provided with a spring rod (t 21), a stress plate (t 22) and a fixed plate (t 23), the spring rod (t 21) is embedded and fixed on the outer side of the stress plate (t 22), the spring rod (t 21) is installed on the inner side of the fixed plate (t 23), and the stress plate (t 22) is in sliding fit with the sliding rod (t 3).