CN116618493A - Electrolyte pipe bending machine - Google Patents

Abstract

The application discloses an electrolyte tube bending machine, which relates to the technical field of bending machines and comprises a machine shell, wherein a power mechanism, a bending mechanism and a clamping mechanism are arranged in the machine shell, the clamping mechanism can clamp an electrolyte tube through a clamping plate after the electrolyte tube is placed in the machine shell, and a first bending plate is pulled through a moving rope fixed on a sliding plate to adjust the bending width to be corresponding to the first bending plate, and the bending mechanism can bend the electrolyte tube placed in the machine shell for the second time, so that the damage to the tube is reduced; through the clamping plate that sets up, can carry out telescopic clamp when the pipe is put into, the removal rope of its fixed will drive its positional relationship of first bending plate and adjust, accomplishes the position of buckling optimally, realizes the size bending of different diameter pipes, and adjusts the distance that the second bending plate was buckled last through pulling adjusting plate to accomplish the adjustment angle of buckling, improved the practicality, and reduced the condition that appears the closed angle when the electrolyte pipe is buckled.

Description

Electrolyte pipe bending machine

Technical Field

The application relates to the field of bending machines, in particular to an electrolyte tube bending machine.

Background

The electrolyte is a medium used by a chemical battery, an electrolytic capacitor and the like, the content of the electrolyte is relatively poor, the electrolyte is required to be arranged in an electrolyte barrel and sucked out through the electrolyte pipe, but the electrolyte pipes with different bending degrees are required due to different sizes and different using places of the electrolyte barrel, and a pipe bender on the market is generally uniform in length and diameter and uniform bending degree, so that the bending angle is required to be manually adjusted in the later stage, the bending machine is very inconvenient, and the metal pipe is directly bent at one time, so that sharp angles are easily generated, the usability of the metal pipe is influenced, even waste is caused.

Disclosure of Invention

Aiming at the defects of the prior art, the application provides an electrolyte tube bending machine.

The application provides the following technical scheme: the bending machine for the electrolyte tube comprises a machine shell, wherein a power mechanism, a bending mechanism and a clamping mechanism are arranged in the machine shell, the clamping mechanism can clamp the electrolyte tube through a clamping plate after the electrolyte tube is placed in the machine shell, the first bending plate is pulled through a moving rope fixed on a sliding plate, the bending width is adjusted to be corresponding to the first bending plate, the bending mechanism can bend the placed electrolyte tube for the second time, damage to the tube is reduced, and when the angle is required to be adjusted, the clamping mechanism can pull the adjusting plate to the front end, the bending distance of the connecting plate is reduced, and therefore the bending angle is adjusted;

the bending mechanism comprises a bending cavity arranged in the casing, the bending cavity is connected with a moving plate in a sliding manner, the moving plate is internally provided with a moving cavity, the moving block is connected with a moving block in a sliding manner, the first bending plate is fixedly connected with the front end surface of the moving block, the second bending starting button is fixedly connected with the rear end wall of the bending cavity, a rear cavity is arranged in the casing, the connecting plate is connected with the sliding manner in the rear cavity in a sliding manner, the second bending plate is fixedly connected with the connecting plate, the sliding cavity is arranged in the casing, the adjusting plate is connected with an adjusting plate in a sliding manner, the adjusting plate is fixedly connected with a stop button, the rotating cavity is arranged in the casing, the left end wall of the rotating cavity is connected with a rotating shaft in a rotating manner, the rotating gear and the driving plate are fixedly connected with a connecting rod in a rotating manner, the connecting rod is hinged with the moving plate, the upper end wall of the rotating cavity is fixedly connected with a fixed column, the rotating shaft is connected with the fixed column in a rotating manner, and the left end wall of the rotating shaft is connected with a linkage shaft in a rotating manner, and the linkage gear is meshed with the gear.

Preferably, the clamping mechanism comprises a clamping cavity arranged in the machine shell, a sliding plate is slidably connected in the clamping cavity, a movable rope is arranged between the sliding plate and the movable block, the sliding plate is fixedly connected with a clamping plate, the lower end face of the clamping plate is fixedly connected with a connecting block, the front end face of the clamping plate is fixedly connected with a stopping block, an adjusting cavity is arranged in the machine shell, the adjusting cavity is rotationally connected with rotary teeth, the rotary teeth are fixedly connected with rotary buttons, an adjusting rope is arranged between the rotary buttons and the adjusting plate, a standing cavity is arranged in the machine shell, a starting button is fixedly connected in the standing cavity, a placing cavity is arranged in the machine shell, and auxiliary bending equipment is slidably connected in the placing cavity.

Preferably, the power mechanism comprises a power cavity arranged in the casing, a power motor is fixedly connected to the front end surface of the power cavity, a power shaft is connected to the power motor in a power mode, a driving gear and a driving bevel gear are fixedly connected to the power shaft, two driven shafts are connected to the lower end surface of the power cavity in a rotating mode, a ratchet wheel is fixedly connected to the driven shafts, a rotary cavity is fixedly connected to the inside of the casing, a first electromagnetic block is fixedly connected to the left end surface of the rotary cavity, a pawl meshed with the ratchet wheel is connected to the left end surface of the rotary cavity in a sliding mode, a driving motor is connected to the rear end wall of the power cavity in a sliding mode, a worm gear is connected to the power motor in a power mode, one worm gear is connected with the worm, an idler gear is arranged between the worm gear and the worm, a rack meshed with the worm gear is connected to the lower end surface of the power cavity in a sliding mode, a rotary magnet is fixedly connected to the right end surface of the rotary cavity, a driving cavity is arranged in the casing, a rotary shaft is connected to the left end surface of the rotary cavity in a rotary mode, a rotary shaft is connected to the rotary shaft sleeve, a rotary shaft is fixedly connected to the rotary shaft sleeve is connected to the rotary shaft sleeve, a control rope is connected to the rotary shaft sleeve is fixedly connected to the rotary sleeve, and the rotary sleeve is connected to the rotary shaft sleeve, and the rotary sleeve is fixedly connected to the rotary shaft is connected to the rotary shaft sleeve, and the rotary shaft is connected to the rotary shaft and the rotary shaft is connected to the rotary shaft.

The application provides an electrolyte tube bending machine, which has the following beneficial effects:

1. according to the application, through the arranged clamping plates, telescopic clamping can be performed when the pipe is put in, the fixed movable rope drives the first bending plate to adjust the position relation of the first bending plate, so that the optimal bending direction is completed, and the bending of pipes with different diameters is realized.

2. According to the application, through the first bending plate and the second bending plate, the electrolyte tube can be bent for the second time, the electrolyte tube is bent for a small extent through the first bending plate, then is bent for the last time through the second bending plate, and the distance of the last bending of the second bending plate is adjusted by pulling the adjusting plate, so that the adjustment of the bending angle is completed, the practicability is improved, and the sharp corner condition when the electrolyte tube is bent is reduced.

Drawings

FIG. 1 is a three-dimensional schematic diagram of an electrolyte tube bender according to the present application;

FIG. 2 is a schematic view of the internal structure of an electrolyte tube bending machine according to the application;

FIG. 3 is a schematic illustration of the structure of A-A of FIG. 2 in accordance with the present application;

FIG. 4 is a schematic view of the structure of B-B in FIG. 3 according to the present application;

FIG. 5 is a schematic view of the structure of C-C of FIG. 2 in accordance with the present application;

FIG. 6 is a schematic diagram of the structure of D-D in FIG. 2 according to the present application;

FIG. 7 is a schematic diagram of the structure of E-E of FIG. 2 in accordance with the present application.

Detailed Description

The following description of the embodiments of the present application 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 application, but not all embodiments. All other embodiments, based on the embodiments of the application, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of the application;

in the description of the present application, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the simplified description of the present application, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

As shown in fig. 1 to 7, an electrolyte tube bending machine according to an embodiment of the present application includes a casing 10, wherein a power mechanism 90, a bending mechanism 91 and a clamping mechanism 92 are provided in the casing 10, the clamping mechanism 92 can clamp an electrolyte tube through a clamping plate 34 after the electrolyte tube is placed in the casing, and pull a first bending plate 22 through a moving rope 18 fixed on a sliding plate 30 to adjust the bending width so as to correspond to the first bending plate, the bending mechanism 91 can perform secondary bending on the placed electrolyte tube, damage to the tube is reduced, and when an adjustment angle is required, the clamping mechanism 92 can pull an adjusting plate 31 to the front end, reduce the bending distance of a connecting plate 23, and thus adjust the bending angle;

the bending mechanism 91 comprises a bending cavity 73 arranged in the casing 10, the bending cavity 73 is connected with a moving plate 17 in a sliding manner, a moving cavity 19 is arranged in the moving plate 17, a moving block 21 is connected in the moving cavity 19 in a sliding manner, a first bending plate 22 is fixedly connected to the front end face of the moving block 21, a return spring 16 is arranged between the moving block 21 and the moving cavity 19, a second bending start button 79 is fixedly connected to the rear end wall of the bending cavity 73, a rear cavity 75 is arranged in the casing 10, a connecting plate 23 is connected in a sliding manner in the rear cavity 75, a second bending plate 24 is fixedly connected to the connecting plate 23, a spring 76 is arranged between the rear cavity 75, a sliding cavity 59 is arranged in the casing 10, an adjusting plate 31 is connected in a sliding manner in the sliding manner, a stop button 77 is arranged in the casing 10, a rotating cavity 72 is connected to the left end wall of the rotating mechanism in a rotating manner, a rotating shaft 69 is fixedly connected to a rotating gear 68, a driving plate 67 is connected to the rotating shaft 67, a rotating shaft 66 is connected to the rotating shaft 71, a connecting rod 71 is fixedly connected to the rotating shaft 68, and the rotating shaft 71 is fixedly connected to the rotating shaft 71.

In a preferred embodiment, the clamping mechanism 92 includes a clamping cavity 32 provided in the casing 10, a sliding plate 30 is slidably connected in the clamping cavity 32, a moving rope 18 is provided between the sliding plate 30 and the moving block 21, the sliding plate 30 is fixedly connected with a clamping plate 34, a connecting block 35 is fixedly connected to a lower end surface of the clamping plate 34, a stop block 33 is fixedly connected to a front end surface of the clamping plate 34, an adjusting cavity 11 is provided in the casing 10, the adjusting cavity 11 is rotatably connected with a rotary tooth 13, the rotary tooth 13 is fixedly connected with a rotary knob 12, an adjusting rope 15 is provided between the rotary knob 12 and the adjusting plate 31, a standing cavity 37 is provided in the casing 10, a start button 26 is fixedly connected in the standing cavity 37, a placing cavity 29 is provided in the casing 10, an auxiliary bending device 27 is slidably connected to the placing cavity 29, and an adjusting spring 28 is provided between the auxiliary bending device 27 and the placing cavity 29.

In a preferred embodiment, the power mechanism 90 includes a power chamber 47 disposed in the casing 10, a power motor 41 is fixedly connected to a front end surface of the power chamber 47, the power motor 41 is in power connection with a power shaft 40, the power shaft 40 is fixedly connected with a driving gear 65 and a driving bevel gear 54, two driven shafts 36 are rotatably connected to a lower end surface of the power chamber 47, the driven shaft 36 is fixedly connected with a ratchet 48, a turning chamber 39 is fixedly connected in the casing 10, a first electromagnetic block 38 is fixedly connected to a left end surface of the turning chamber 39, a pawl 45 engaged with the ratchet 48 is slidably connected in the turning chamber 39, a driving spring 44 is disposed between the pawl 45 and the turning chamber 39, a rotating spring 43 is disposed between the driven shaft 36 and the power chamber 47, a rear end wall of the power chamber 47 is not connected with a driving motor 80, the driving motor 80 is in power connection with a worm 81, one of the driven shafts 36 is fixedly connected with the worm 81, another worm gear wheel 42 is connected with the worm 81, a turning gear 20 is disposed between the worm wheel 81 and the worm gear 81, the lower end surface of the worm gear 20 is in the turning chamber 52 is in direct connection with the driving gear 52, a rotating shaft 52 is fixedly connected with the rotating shaft 52, a rotating shaft 52 is disposed between the rotating shaft 52 and the rotating chamber 52, a rotating shaft 52 is fixedly connected with the rotating shaft 52, a rotating shaft 52 is disposed between the rotating shaft 52, a rotating shaft 52 is connected with the rotating shaft 52, and a rotating shaft 52 is connected between the rotating shaft 52, and a rotating shaft 52, a rotating shaft is connected between the rotating shaft 52, and a casing is connected between a rotating shaft and a casing 52, and a casing, and a rotating gear is connected. The rotary shaft 62 is fixedly connected with a control shaft sleeve 63, a switching cavity 14 is arranged in the casing 10, a magnet 64 is fixedly connected to the front end surface in the switching cavity 14, a connecting spring 78 is arranged between the control shaft sleeve 63 and the switching cavity 14, the control shaft sleeve 63 is fixedly connected with a driven gear 61 and a rope winder 60, and a pulling rope 25 is arranged between the rope winder 60 and the connecting plate 23.

The application relates to an electrolyte tube bending machine, which comprises the following working procedures:

in the initial state, the clamping plate 34 and the sliding plate 30 are positioned at the two ends, the auxiliary bending device 27 is positioned at the rearmost end, the first bending plate 22 is positioned at the rearmost end, the moving block 21 is positioned at the leftmost end in the moving cavity 19, the second bending plate 24 is positioned at the rearmost end, the driven gear 61 is not meshed with the driving gear 65, the driven bevel gear 55 is not meshed with the driving bevel gear 54, the two racks 46 are positioned at the two ends, and the second bending start button 79 is in the pressed state;

after the prepared electrolyte suction pipe is put into the electrolyte suction pipe, the power motor 41 and the driving motor 80 are started, the worm 81 starts to rotate, the idler wheel 20 is driven, the worm wheel 42 is driven to rotate, the two racks 46 are driven to move inwards, the connecting block 35 is driven, the two clamping plates 34 are driven to fix the electrolyte pipe inwards, the sliding plate 30 moves inwards to tighten the moving rope 18, the moving block 21 is pulled to move rightwards, the first bending plate 22 is driven to move rightwards, the distance between the bending pipes is adjusted, the bending pipes are easier to bend, when the clamping electrolyte pipe presses down the stopping block 33, the driving motor 80 stops, the worm wheel 42 is not rotated due to the fact that the pawl 45 clamps the ratchet wheel 48, the worm wheel 42 is not rotated, the clamping electrolyte pipe is fixed, the lower end face of the electrolyte pipe touches the starting button 26, the switching magnet 50 is started, the switching magnet 50 is electrified to suck the shaft sleeve 52 to the right end, the driven bevel gear 55 is driven to move rightwards to be meshed with the driving bevel gear 54, so that the linkage gear 57 rotates, the linkage gear 57 drives the linkage gear 70, the linkage gear 70 drives the rotation gear 68 to rotate, thereby driving the driving plate 67 fixed on the rotation gear 68 to rotate, the driving plate 67 rotates to push the connecting rod 66 to the right end, because the moving plate 17 is fixed in the chute and only can do sliding motion, the moving plate 17 is not moved up and down, thereby pushing the moving plate 17, pushing the first bending plate 22 to move to the right, bending the electrolyte tube, when the moving block 21 moves, the second bending start button 79 is released, the magnet 64 is started after 2 seconds, the control shaft sleeve 63 is pushed to the rear end, the driven gear 61 is driven to be meshed with the driving gear 65, thereby rotating the rotating shaft 62, the rope winder 60 pulls the rope 25, the connecting plate 23 is pulled forward, the bent half of the tube is bent forward again, thereby completing the bending of the electrolyte tube;

when the connecting plate 23 touches the stop button 77, the motor stops, the connecting plate 23 moves back under the reaction of the spring 76, meanwhile, the first electromagnetic block 38 is magnetized to suck the pawl 45 to the front end, the first electromagnetic block 38 rotates back under the action of the rotary spring 43 to reset the rack 46, so that the clamping plate 34 clamping the electrolyte tube is loosened, and when the bending angle needs to be adjusted, only the rotary button 12 is required to be rotated, the rotary button 12 drives the rotary teeth 13 to grab, the adjusting rope 15 is tightened, and the adjusting plate 31 is pulled to the front end, so that the bending angle of pushing by the second bending plate 24 is reduced.

It should be understood that the above-described embodiments are merely exemplary and are not intended to limit the present application. Those skilled in the art can make various modifications and changes to the above-described embodiments without departing from the scope of the present application.

Claims (8)

1. Electrolyte pipe bender, including casing (10), its characterized in that: the electrolyte tube bending machine comprises a machine shell (10), wherein a power mechanism (90), a bending mechanism (91) and a clamping mechanism (92) are arranged in the machine shell (10), the clamping mechanism (92) can clamp the electrolyte tube through a clamping plate (34) after the electrolyte tube is placed in the machine shell, a first bending plate (22) is pulled through a moving rope (18) fixed on a sliding plate (30), the bending width is adjusted to be corresponding to the first bending plate, the bending mechanism (91) can carry out secondary bending on the placed electrolyte tube, damage to the tube is reduced, and when an angle is required to be adjusted, the clamping mechanism (92) can pull an adjusting plate (31) to the front end, and the bending distance of a connecting plate (23) is reduced, so that the bending angle is adjusted; the bending mechanism (91) comprises a bending cavity (73) arranged in the shell (10).

2. An electrolyte tube bender according to claim 1, wherein: the utility model discloses a bending cavity (73) sliding connection has movable plate (17), be equipped with in movable plate (17) and remove chamber (19), be connected with movable block (21) in movable plate (19) in the sliding connection, terminal surface fixedly connected with first bending plate (22) before movable block (21), movable block (21) with be equipped with reset spring (16) between movable chamber (19), end wall fixedly connected with second bending start button (79) after bending cavity (73), be equipped with back position chamber (75) in casing (10), sliding connection has connecting plate (23) in back position chamber (75), connecting plate (23) fixedly connected with second bending plate (24), connecting plate (23) with be equipped with spring (76) between back position chamber (75).

3. An electrolyte tube bender according to claim 1, wherein: be equipped with sliding chamber (59) in casing (10), sliding connection has regulating plate (31) in sliding chamber (59), regulating plate (31) fixedly connected with stop button (77), be equipped with in casing (10) and rotate chamber (72), it even has pivot (69) to rotate chamber (72) left end wall rotation, pivot (69) fixedly connected with rotation gear (68) and drive plate (67), drive plate (67) rotation is connected with connecting rod (66), connecting rod (66) articulates there is movable plate (17), rotate chamber (72) upper end wall fixedly connected with fixed column (74), pivot (69) rotation is connected with fixed column (74), it is connected with linkage axis (71) to rotate chamber (72) left end wall rotation, linkage axis (71) fixedly connected with gear (70) of rotation gear (68) meshing.

4. An electrolyte tube bender according to claim 1, wherein: in a preferred embodiment, the clamping mechanism (92) comprises a clamping cavity (32) arranged in the casing (10), a sliding plate (30) is slidably connected in the clamping cavity (32), a moving rope (18) is arranged between the sliding plate (30) and the moving block (21), the sliding plate (30) is fixedly connected with a clamping plate (34), the lower end face of the clamping plate (34) is fixedly connected with a connecting block (35), the front end face of the clamping plate (34) is fixedly connected with a stopping block (33), an adjusting cavity (11) is arranged in the casing (10), and the adjusting cavity (11) is rotationally connected with a rotary tooth (13).

5. An electrolyte tube bender according to claim 1, wherein: the rotary tooth (13) is fixedly connected with a rotary button (12), an adjusting rope (15) is arranged between the rotary button (12) and the adjusting plate (31), a standing cavity (37) is arranged in the machine shell (10), a starting button (26) is fixedly connected in the standing cavity (37), a placing cavity (29) is arranged in the machine shell (10), an auxiliary bending device (27) is connected in the placing cavity (29) in a sliding mode, and an adjusting spring (28) is arranged between the auxiliary bending device (27) and the placing cavity (29).

6. An electrolyte tube bender according to claim 1, wherein: in a preferred embodiment, the power mechanism (90) comprises a power cavity (47) arranged in the casing (10), a power motor (41) is fixedly connected to the front end surface of the power cavity (47), the power motor (41) is in power connection with a power shaft (40), a driving gear (65) and a driving bevel gear (54) are fixedly connected to the power shaft (40), two driven shafts (36) are rotatably connected to the lower end surface of the power cavity (47), a ratchet wheel (48) is fixedly connected to the driven shafts (36), a rotary cavity (39) is fixedly connected to the casing (10), a first electromagnetic block (38) is fixedly connected to the left end surface of the rotary cavity (39), a pawl (45) meshed with the ratchet wheel (48) is connected to the rotary cavity (39) in a sliding mode, and a driving spring (44) is arranged between the pawl (45) and the rotary cavity (39).

7. An electrolyte tube bender according to claim 1, wherein: the novel energy-saving power supply is characterized in that a rotary spring (43) is arranged between the driven shaft (36) and the power cavity (47), a driving motor (80) is not connected to the rear end wall of the power cavity (47), a worm (81) is connected to the driving motor (80) in a power mode, the driven shaft (36) is fixedly connected with a worm wheel (42), one worm wheel (42) is kneaded with the worm (81), an idler wheel (20) is arranged between the worm wheel (42) and the worm (81), racks (46) meshed with the worm wheel (42) are slidingly connected to the lower end face of the power cavity (47), connecting blocks (35) are fixedly connected to the racks (46), a conversion cavity (49) is arranged in the casing (10), a conversion magnet (50) is fixedly connected to the right end face of the conversion cavity (49), a driving cavity (53) is arranged in the casing (10), a rotary shaft (56) is rotationally connected to the left end face of the driving cavity (53), and a shaft sleeve (52) and a linkage gear (57) are fixedly connected to the rotary shaft (56).

8. An electrolyte tube bender according to claim 1, wherein: control spring (51) is arranged between the shaft sleeve (52) and the conversion cavity (49), driven bevel gear (55) is fixedly connected with the shaft sleeve (52), communication cavity (58) is arranged in the shell (10), a rotating shaft (62) is rotationally connected with the rear end face of the communication cavity (58), control shaft sleeve (63) is fixedly connected with the rotating shaft (62), switching cavity (14) is arranged in the shell (10), magnet (64) is fixedly connected with the front end face in the switching cavity (14), connecting spring (78) is arranged between the control shaft sleeve (63) and the switching cavity (14), driven gear (61) and a rope winder (60) are fixedly connected with the control shaft sleeve (63), and a pulling rope (25) is arranged between the rope winder (60) and the connecting plate (23).