CN118617106A - A processing equipment for cooling tower splash device - Google Patents

Abstract

The present invention discloses a processing equipment for a cooling tower splash device, and relates to the technical field of pipeline processing. The present invention comprises an equipment main body, a U-shaped frame is fixed on the top of the equipment main body, a hydraulic cylinder is fixed on the top of the U-shaped frame, a punch is fixed on the bottom of the telescopic end of the hydraulic cylinder, an arc panel is fixed on the top of the equipment main body, electric control clamps are fixed on the front and rear sides of the arc panel, an L-shaped arc surface slide plate is installed horizontally and slidably below the arc panel, and a circular frame is fixed on the top right side of the equipment main body. The present invention drives a through-hole spring plate to form a support on the top of the inner wall of the spray pipe through the cooperation of a threaded rod, a threaded block, a circular frame, and a horizontal column. The through-hole spring plate as a support can effectively enhance the structural strength of the top of the spray pipe, thereby preventing the spray pipe wall from being greatly deformed or damaged during punching, and maintaining the overall shape and structural stability of the spray pipe.

Description

A processing equipment for cooling tower splash device

Technical Field

The invention relates to the technical field of pipeline processing, in particular to processing equipment for a cooling tower splashing device.

Background Art

Splash pipes are used in the process of using the splash device of the cooling tower. Splash pipes are also called spray pipes, which are key components used in hydraulic spray systems. They are usually made of corrosion-resistant materials (such as plastics or metal alloys) and have multiple small holes or nozzles. They drive the water flow through pressure to spray or spray water evenly to the area that needs to be wetted, cleaned or cooled. Punching equipment is used in the processing of spray pipes to punch them.

The patent with the patent announcement number CN212551279U discloses a pipe punching device, including a workbench, two slide rails are fixedly installed on the top of the workbench, one side of the inner cavity of the two slide rails is rotatably connected with a transverse screw rod, the outer sides of the two transverse screw rods are threadedly connected with a slider, and the tops of the two sliders pass through the slide rail and extend to the top of the slide rail. The patent is provided with a meter counter and a transverse screw rod, the transverse screw rod rotates to drive the slider to move along the bottom of the inner cavity of the slide rail in an appropriate direction, and the transverse screw rod rotates to drive the meter counter to run, and the meter counter transmits numerical information to the control panel, so that the operator can accurately control the position of the punch; by providing a conveying trough and a waste box, the piston rod of the first cylinder pushes the punch to punch the pipe, and the residual material produced by the punching falls into the conveying trough, and falls from the waste trough into the waste box under the action of gravity, which is convenient for collecting the residual material.

However, the current processing equipment has the following problems: the processing equipment is not convenient for forming support for the inner wall of the spray pipe when punching the spray pipe; when punching thinner spray pipes, the thinner spray pipes cannot evenly withstand the impact force, resulting in irregular hole shapes or uneven edges at the punching parts of the spray pipes, which will affect the subsequent connection or installation of the spray pipes.

Summary of the invention

In view of the deficiencies in the prior art, the present invention provides a processing equipment for a cooling tower splashing device, which solves the problems raised in the above-mentioned background technology.

To achieve the above purpose, the present invention is implemented through the following technical solutions: a processing equipment for a cooling tower splashing device, comprising an equipment body, a U-shaped frame is fixed on the top of the equipment body, a hydraulic cylinder is fixed on the top of the U-shaped frame, a punch is fixed on the bottom of the telescopic end of the hydraulic cylinder, an arc panel is fixed on the top of the equipment body, electric control clamps are fixed on the front and rear sides of the arc panel, an L-shaped arc slide is installed horizontally and slidably below the arc panel, a circular frame is fixed on the top right side of the equipment body, a threaded rod is rotatably installed inside the circular frame, and the threaded rod is driven by a motor, the external thread of the threaded rod is connected to a threaded block, and the threaded block is slidably installed inside the circular frame, a cross column is fixed on the left side of the threaded block, a long groove for sliding the cross column is opened on the outer wall of the L-shaped arc slide, and a groove is opened on the left top of the cross column, A through-hole spring plate is fixed above the inner wall of the groove of the horizontal column. The threaded rod drives the threaded block to move upward along the inner wall of the circular frame. The threaded block drives the horizontal column to move upward. The horizontal column drives the through-hole spring plate to fit with the top of the inner wall of the spray pipe, so that the through-hole spring plate forms a support on the top of the inner wall of the spray pipe.

According to the above technical scheme, a resistance wheel is rotatably installed on the left end of the horizontal column, and cam wheels are fixed on the front and rear sides of the rotating shaft of the resistance wheel. A knocking column is penetrated and slidably installed on the bottom of the inner wall of the groove of the horizontal column, and a spring is provided between the knocking column and the bottom of the inner wall of the groove of the horizontal column. The top of the knocking column contacts the bottom of the through-hole spring plate, and a connecting plate is fixed to the bottom of the knocking column. Two L-shaped rods are fixed on the left side of the connecting plate. A semi-arc cam is fixed on the outside of the cam wheel, and the end of the L-shaped rod away from the connecting plate is semi-arc shaped. The semi-arc shape of the L-shaped rod is located on the semi-arc cam movement trajectory of the cam wheel. When the spray pipe is punching the next hole position , pushing the spray pipe toward the circular frame, the spray pipe pushes the L-shaped arc slide plate to move with it, and under the friction force between the resistance wheel and the inner wall of the spray pipe, the spray pipe will drive the resistance wheel to rotate when moving, and the resistance wheel drives the bump wheel to rotate, and the semi-arc bump of the bump wheel pushes the semi-arc shape of the L-shaped rod to drive the L-shaped rod to move downward, and the L-shaped rod drives the knocking column to move downward through the connecting plate, and the spring corresponding to the knocking column is compressed, and the knocking column moves away from the through-hole spring plate. When the semi-arc bump of the bump wheel no longer pushes the semi-arc shape of the L-shaped rod, under the action of the spring force corresponding to the knocking column, the knocking column resets and moves upward, and the knocking column knocks the through-hole spring plate, causing the through-hole spring plate to vibrate.

According to the above technical scheme, the outside of the horizontal column is sleeved with an internal grinding device, and the internal grinding device includes a slider, a spiral groove sleeve, a telescopic ring, and two grinding brushes. The slider is slidably installed at the right outer wall of the L-shaped arc surface slider, and an annular groove is opened on the right outer side of the horizontal column. The spiral groove sleeve is rotatably installed on the right side of the annular groove of the horizontal column. The spiral groove sleeve passes through the slider, and the inside of the slider is fixed with a protrusion for sliding installation inside the spiral groove of the spiral groove sleeve. The fixed end of the telescopic ring is fixed to the left side of the spiral groove sleeve, and the telescopic ring is sleeved on the outside of the annular groove of the horizontal column. The two grinding brushes are fixed on the outside of the telescopic ring. When the spray pipe pushes the L-shaped arc surface slider to move, the L-shaped arc surface slider drives the slider to move, and the protrusion of the slider slides along the spiral groove of the spiral groove sleeve. The protrusion of the slider will drive the spiral groove sleeve to rotate, the spiral groove sleeve drives the telescopic ring to rotate, and the telescopic ring drives the grinding brush to rotate.

According to the above technical scheme, the internal grinding device includes a semicircular block 1 and several semicircular blocks 2. The semicircular block 1 is fixed at the left edge of the telescopic end of the telescopic ring, and several semicircular blocks 2 are evenly and equidistantly fixed on the left side of the inner wall of the annular groove of the horizontal column. The semicircular surfaces of the semicircular block 2 and the semicircular block 1 are relatively arranged, and the semicircular surface of the semicircular block 2 is located on the movement trajectory of the semicircular surface of the semicircular block 1. At the same time, the rotation of the telescopic ring will drive the semicircular block 1 to rotate, and the semicircular surface of the semicircular block 2 pushes the semicircular surface of the semicircular block 1 to drive the telescopic end of the telescopic ring to move to the right. When the semicircular surface of the semicircular block 2 no longer pushes the semicircular surface of the semicircular block, the telescopic end of the telescopic ring is reset and moves to the left under the action of its own elastic force, and so on. The telescopic end of the telescopic ring drives the grinding brush to move back and forth.

According to the above technical solution, stabilizing devices are provided on both sides below the telescopic end of the hydraulic cylinder, and the stabilizing devices include an elastic telescopic rod and a suction cup. The elastic telescopic rod is fixed to the bottom of the telescopic end of the hydraulic cylinder, and the suction cup is hinged to the bottom of the telescopic end of the elastic telescopic rod. When the telescopic end of the hydraulic cylinder drives the punch to punch the spray pipe, the telescopic end of the hydraulic cylinder will first drive the elastic telescopic rod to move downward, and the telescopic end of the elastic telescopic rod drives the suction cup to contact the top of the spray pipe first. Under the elastic force of the elastic telescopic rod, the elastic telescopic rod drives the suction cup to be pressed on the top of the spray pipe.

According to the above technical scheme, the stabilizing device also includes an L-shaped push rod, an air tube, a fixed plate, and a folding bag. The fixed plate is fixed at the outer wall of the fixed end of the elastic telescopic rod, and the folding bag is fixed at the top of the fixed plate. One end of the L-shaped push rod is fixed at the outer wall of the telescopic end of the elastic telescopic rod, and the other end of the L-shaped push rod is fixed at the top of the inner wall of the folding bag, and the other end of the L-shaped push rod passes through the fixed plate, one end of the air tube is embedded in the bottom of the fixed plate, and the other end of the air tube is embedded in the outer wall of the suction cup. At the same time, when the telescopic end of the elastic telescopic rod contracts, the telescopic end of the elastic telescopic rod drives the L-shaped push rod toward the fixed plate, and the L-shaped push rod pushes the folding bag to stretch. The folding bag absorbs the air at the suction cup through the air tube, thereby generating negative pressure at the suction cup.

The present invention provides a processing device for a cooling tower splashing device. It has the following beneficial effects:

(1) The present invention drives the through-hole spring plate to form a support on the top of the inner wall of the spray pipe through the cooperation of the threaded rod, the threaded block, the circular frame, and the horizontal column. The through-hole spring plate as a support can effectively enhance the structural strength of the top of the spray pipe, thereby preventing the spray pipe wall from being greatly deformed or damaged during punching, thereby maintaining the overall shape and structural stability of the spray pipe; at the same time, the circular frame, the L-shaped arc-surface slide plate, the abutment wheel, the cam wheel, the L-shaped rod, and the connecting plate cooperate to drive the knocking column to knock the through-hole spring plate, causing the through-hole spring plate to vibrate, and the through-hole spring plate shakes off the metal debris that sneaks into the space between the through-hole spring plate and the spray pipe, thereby avoiding the accumulation of metal debris between the through-hole spring plate and the spray pipe, resulting in an uneven gap between the through-hole spring plate and the spray pipe, resulting in the problem that the through-hole spring plate cannot stably support the spray pipe;

(2) The present invention sets an internal grinding device so that the L-shaped arc surface slide plate, the slider, the spiral groove sleeve, and the telescopic ring cooperate to drive the grinding brush to grind the inner wall of the spray pipe punching hole. The grinding brush can effectively remove the burrs generated when the spray pipe wall is punched, thereby making the hole of the spray pipe wall punching hole smoother and safer, thereby reducing the probability of workers being scratched by burrs; at the same time, the telescopic ring, the semicircular block 1, and the semicircular block 2 cooperate to drive the grinding brush to dynamically grind the inner wall of the spray pipe punching hole, thereby further improving the effect of the grinding brush on the inner wall of the spray pipe punching hole.

(3) The present invention sets a stabilizing device so that the hydraulic cylinder and the elastic telescopic rod cooperate to drive the suction cup to press on the top of the spray pipe. The elastic telescopic rod can drive the suction cup to effectively fix and stabilize the spray pipe to prevent it from moving or shaking during the punching process, thereby improving the accuracy and consistency of the spray pipe punching; at the same time, the elastic telescopic rod, L-shaped push rod, fixing plate, and folding bag cooperate to drive the suction cup to generate negative pressure, and the suction cup adsorbs and fixes the spray pipe. The suction cup can stabilize the position of the spray pipe, thereby ensuring that the punch accurately passes through the wall of the spray pipe without deviation or distortion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the present invention as a whole;

Fig. 2 is a partial cross-sectional schematic diagram of the present invention;

FIG3 is a schematic diagram of a partial structure of the present invention;

FIG4 is a schematic cross-sectional view of a horizontal column of the present invention;

FIG5 is a schematic diagram of an internal grinding device of the present invention;

FIG6 is an enlarged schematic diagram of the structure at A in FIG5 of the present invention;

FIG7 is a partial cross-sectional schematic diagram of a stabilizing device of the present invention;

FIG8 is a schematic diagram showing the positional relationship among the horizontal column, the through-hole spring plate and the knocking column of the present invention;

FIG. 9 is a schematic diagram showing the positional relationship between the transverse column and the spiral groove sleeve of the present invention.

In the figure: 1. Equipment body; 2. U-shaped frame; 3. Arc panel; 4. Hydraulic cylinder; 5. Punch; 6. Internal grinding device; 61. Slider; 62. Spiral groove sleeve; 63. Telescopic collar; 64. Grinding brush; 65. Semicircular block 1; 66. Semicircular block 2; 7. Stabilizing device; 71. Elastic telescopic rod; 72. Suction cup; 73. L-shaped push rod; 74. Air pipe; 75. Fixed plate; 76. Folding bag; 8. L-shaped arc slide plate; 81. Long groove; 9. Reciprocating frame; 10. Electric control fixture; 11. Threaded block; 12. Threaded rod; 13. Horizontal column; 131. Groove; 132. Annular groove; 14. Through-hole spring plate; 15. Resistance wheel; 16. Bump wheel; 17. L-shaped rod; 18. Connecting plate; 19. Knocking column.

DETAILED DESCRIPTION

The technical solutions in the embodiments of the present invention will be described clearly and completely below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, rather than all the embodiments.

Please refer to Figures 1-9. An embodiment of the present invention is: a processing equipment for a cooling tower splashing device, including an equipment body 1, a U-shaped frame 2 is fixed on the top of the equipment body 1, a hydraulic cylinder 4 is fixed on the top of the U-shaped frame 2, a punch 5 is fixed on the bottom of the telescopic end of the hydraulic cylinder 4, an arc panel 3 is fixed on the top of the equipment body 1, and an electric control clamp 10 is fixed on the front and rear sides of the arc panel 3. An L-shaped arc surface slide plate 8 is installed horizontally and slidably below the arc panel 3, a circular frame 9 is fixed on the top of the right side of the equipment body 1, and the L-shaped arc surface slide plate 8 is located on the left side of the circular frame 9, a threaded rod 12 is rotatably installed inside the circular frame 9, and the threaded rod 12 is driven by a motor, the external thread of the threaded rod 12 is connected to a threaded block 11, and the threaded block 11 is slidably installed inside the circular frame 9, a cross column 13 is fixed on the left side of the threaded block 11, a long groove 81 for sliding of the cross column 13 is opened on the outer wall of the L-shaped arc surface slide plate 8, and a groove 131 is opened on the left top of the cross column 13, A through-hole spring plate 14 is fixed above the inner wall of the groove 131 of the horizontal column 13. Through the arrangement of the above-mentioned structure, the through-hole spring plate 14 forms a support on the top of the inner wall of the spray pipe. The through-hole spring plate 14 as a support can effectively enhance the structural strength of the top of the spray pipe, thereby preventing the spray pipe wall from being greatly deformed or damaged during punching, thereby maintaining the overall shape and structural stability of the spray pipe.

The left end of the horizontal column 13 is rotatably mounted with a resistance wheel 15, and the front and rear sides of the rotating shaft of the resistance wheel 15 are fixed with a cam wheel 16. The bottom of the inner wall of the groove 131 of the horizontal column 13 passes through and is slidably mounted with a knocking column 19, and a spring is provided between the knocking column 19 and the bottom of the inner wall of the groove 131 of the horizontal column 13. The top of the knocking column 19 contacts the bottom of the through-hole spring plate 14, and the bottom of the knocking column 19 is fixed with a connecting plate 18. Two L-shaped rods 17 are fixed on the left side of the connecting plate 18. A semi-arc cam is fixed on the outside of the cam wheel 16, and the L-shaped rod 17 is away from the connecting plate One end of 18 is arranged in a semi-arc shape, and the semi-arc shape of the L-shaped rod 17 is located on the semi-arc protrusion movement trajectory of the protrusion wheel 16. Through the arrangement of the above structure, the knocking column 19 knocks the through-hole spring plate 14, and the through-hole spring plate 14 vibrates. The through-hole spring plate 14 shakes off the metal debris that sneaks into the space between the through-hole spring plate 14 and the spray pipe, thereby avoiding the accumulation of metal debris between the through-hole spring plate 14 and the spray pipe, causing an uneven gap to be formed between the through-hole spring plate 14 and the spray pipe, resulting in the problem that the through-hole spring plate 14 cannot stably support the spray pipe.

The outer part of the cross column 13 is sleeved with an inner grinding device 6, which includes a slider 61, a spiral groove sleeve 62, a telescopic ring 63, and two grinding brushes 64. The slider 61 is slidably mounted on the right outer wall of the L-shaped curved slide 8. An annular groove 132 is provided on the right outer part of the cross column 13. The spiral groove sleeve 62 is rotatably mounted on the right side of the annular groove 132 of the cross column 13. The spiral groove sleeve 62 passes through the slider 61, and a convex screw for slidingly mounting inside the spiral groove of the spiral groove sleeve 62 is fixed inside the slider 61. The fixed end of the telescopic collar 63 is fixed to the left side of the spiral groove sleeve 62, and the telescopic collar 63 is sleeved on the outside of the annular groove 132 of the horizontal column 13. The two grinding brushes 64 are fixed on the outside of the telescopic collar 63. Through the arrangement of the above structure, the grinding brush 64 can grind the inner wall of the punching hole of the spray pipe. The grinding brush can effectively remove the burrs generated when the wall of the spray pipe is punched, thereby making the hole of the punching hole of the spray pipe smoother and safer, thereby reducing the probability of workers being scratched by burrs.

The inner grinding device 6 includes a semicircular block 1 65 and a plurality of semicircular blocks 2 66. The semicircular block 1 65 is fixed at the left edge of the telescopic end of the telescopic ring 63. The plurality of semicircular blocks 2 66 are evenly and equidistantly fixed on the left inner wall of the annular groove 132 of the horizontal column 13. The semicircular surfaces of the semicircular block 2 66 and the semicircular block 1 65 are arranged relative to each other. The semicircular surface of the semicircular block 2 66 is located on the motion trajectory of the semicircular surface of the semicircular block 1 65. Through the arrangement of the above structure, the rotation of the telescopic ring 63 will drive the semicircular block 1 65 to rotate, and the semicircular surface of the semicircular block 2 66 pushes the semicircular block The semicircular surface of the first 65 drives the telescopic end of the telescopic ring 63 to move to the right. When the semicircular surface of the second semicircular block 66 no longer pushes the semicircular surface of the first semicircular block 65, the telescopic end of the telescopic ring 63 is reset and moves to the left under the action of its own elastic force, and so on. The telescopic end of the telescopic ring 63 drives the grinding brush 64 to move back and forth, and the telescopic end of the telescopic ring 63 drives the grinding brush 64 to move back and forth, so that the grinding brush 64 dynamically grinds the inner wall of the punching hole of the spray pipe, thereby further improving the effect of the grinding brush 64 on the grinding of the inner wall of the punching hole of the spray pipe.

When in use, the spray pipe that needs to be punched is placed on the top of the arc panel 3, and one end of the spray pipe will hit the inner wall of the L-shaped arc slide 8. Then the electric control clamp 10 is started, and the electric control clamp 10 will fix the spray pipe on the top of the arc panel 3. The hydraulic cylinder 4 is started, and the telescopic end of the hydraulic cylinder 4 will drive the punch 5 to punch the spray pipe. When the spray pipe is placed on the arc panel 3, the through-hole spring plate 14 is extended into the inside of the spray pipe. Before the spray pipe is punched, the threaded rod 12 is driven by the motor to rotate, and the threaded rod 12 drives the threaded rod 12 to rotate. The block 11 moves upward along the inner wall of the circular frame 9, the threaded block 11 drives the cross column 13 to move upward, and the cross column 13 drives the through-hole spring plate 14 to fit with the top of the inner wall of the spray pipe, so that the through-hole spring plate 14 forms a support on the top of the inner wall of the spray pipe. The through-hole spring plate 14 as a support can effectively enhance the structural strength of the top of the spray pipe, so as to prevent the spray pipe wall from being greatly deformed or damaged during punching, and maintain the overall shape and structural stability of the spray pipe; when the spray pipe is punching the next hole, the spray pipe is pushed toward The circular frame 9 and the spray pipe push the L-shaped arc surface slide plate 8 to move with it. Under the friction between the resistance wheel 15 and the inner wall of the spray pipe, the spray pipe will drive the resistance wheel 15 to rotate when moving, and the resistance wheel 15 drives the bump wheel 16 to rotate. The semi-arc bump of the bump wheel 16 pushes the semi-arc shape of the L-shaped rod 17 to drive the L-shaped rod 17 to move downward. The L-shaped rod 17 drives the knocking column 19 to move downward through the connecting plate 18. The spring corresponding to the knocking column 19 is compressed, and the knocking column 19 is away from the through-hole spring plate 14. When the semi-arc of the bump wheel 16 When the protrusion no longer pushes the semi-arc shape of the L-shaped rod 17, under the action of the spring force corresponding to the knocking column 19, the knocking column 19 resets and moves upward, and the knocking column 19 knocks the through-hole spring plate 14, and the through-hole spring plate 14 vibrates. The through-hole spring plate 14 shakes off the metal debris that has sneaked into the space between the through-hole spring plate 14 and the spray pipe, thereby avoiding the accumulation of metal debris between the through-hole spring plate 14 and the spray pipe, causing an uneven gap to be formed between the through-hole spring plate 14 and the spray pipe, resulting in the problem that the through-hole spring plate 14 cannot stably support the spray pipe.

When it is necessary to punch the next hole in the spray pipe, the spray pipe is pushed to the right, and the spray pipe will push the L-shaped arc slide 8 to move synchronously. In the process of the spray pipe pushing the L-shaped arc slide 8 to move, the L-shaped arc slide 8 drives the slider 61 to move along, and the protrusion of the slider 61 slides along the spiral groove of the spiral groove sleeve 62, and the protrusion of the slider 61 drives the spiral groove sleeve 62 to rotate, and the spiral groove sleeve 62 drives the telescopic ring 63 to rotate, and the telescopic ring 63 drives the grinding brush 64 to rotate, and the grinding brush 64 will brush the inner wall of the spray pipe punching hole, and the grinding brush can effectively remove the burrs generated when the spray pipe wall is punched, thereby making the spray pipe wall punching hole The orifice is smoother and safer, thereby reducing the probability of workers being scratched by burrs; at the same time, the rotation of the telescopic ring 63 will drive the semicircular block 1 65 to rotate, and the semicircular surface of the semicircular block 2 66 pushes the semicircular surface of the semicircular block 1 65 to drive the telescopic end of the telescopic ring 63 to move to the right. When the semicircular surface of the semicircular block 2 66 no longer pushes the semicircular surface of the semicircular block 1 65, the telescopic end of the telescopic ring 63 is reset and moves to the left under the action of its own elastic force, and so on. The telescopic end of the telescopic ring 63 drives the grinding brush 64 to move back and forth, so that the grinding brush 64 dynamically grinds the inner wall of the punching hole of the spray pipe, thereby further improving the effect of the grinding brush 64 on the grinding of the inner wall of the punching hole of the spray pipe.

Please refer to FIGS. 1-9 . Based on the above embodiment, in another embodiment of the present invention, stabilizing devices 7 are provided on both sides below the telescopic end of the hydraulic cylinder 4 .

The stabilizing device 7 includes an elastic telescopic rod 71 and a suction cup 72. The elastic telescopic rod 71 is fixed to the bottom of the telescopic end of the hydraulic cylinder 4, and the suction cup 72 is hinged to the bottom of the telescopic end of the elastic telescopic rod 71. Through the arrangement of the above structure, the elastic telescopic rod 71 drives the suction cup 72 to be pressed on the top of the spray pipe. The elastic telescopic rod 71 can drive the suction cup 72 to effectively fix and stabilize the spray pipe to prevent it from moving or shaking during the punching process, thereby improving the accuracy and consistency of the punching of the spray pipe.

The stabilizing device 7 also includes an L-shaped push rod 73, an air pipe 74, a fixing plate 75, and a folding bag 76. The fixing plate 75 is fixed to the outer wall of the fixed end of the elastic telescopic rod 71, and the folding bag 76 is fixed to the top of the fixing plate 75. One end of the L-shaped push rod 73 is fixed to the outer wall of the telescopic end of the elastic telescopic rod 71, and the other end of the L-shaped push rod 73 is fixed to the top of the inner wall of the folding bag 76, and the other end of the L-shaped push rod 73 passes through the fixing plate 75, one end of the air pipe 74 is embedded in the bottom of the fixing plate 75, and the other end of the air pipe 74 is embedded in the outer wall of the suction cup 72. Through the arrangement of the above structure, the folding bag 76 absorbs the air at the suction cup 72 through the air pipe 74, so that negative pressure is generated at the suction cup 72, and the suction cup 72 adsorbs and fixes the spray pipe. The suction cup 72 can stabilize the position of the spray pipe, thereby ensuring that the punch 5 accurately passes through the wall of the spray pipe without deviation or distortion.

When in use, when the telescopic end of the hydraulic cylinder 4 drives the punch 5 to punch the spray pipe, the telescopic end of the hydraulic cylinder 4 will first drive the elastic telescopic rod 71 to move downward, and the telescopic end of the elastic telescopic rod 71 drives the suction cup 72 to contact the top of the spray pipe first. Under the elastic force of the elastic telescopic rod 71, the elastic telescopic rod 71 drives the suction cup 72 to press on the top of the spray pipe. The elastic telescopic rod 71 can drive the suction cup 72 to effectively fix and stabilize the spray pipe to prevent it from moving or shaking during the punching process, thereby The accuracy and consistency of the punching of the spray pipe are improved; at the same time, when the telescopic end of the elastic telescopic rod 71 contracts, the telescopic end of the elastic telescopic rod 71 drives the L-shaped push rod 73 to lean against the fixed plate 75, and the L-shaped push rod 73 pushes the folding bag 76 to stretch. The folding bag 76 absorbs the air at the suction cup 72 through the air pipe 74, thereby generating negative pressure at the suction cup 72, and the suction cup 72 adsorbs and fixes the spray pipe. The suction cup 72 can stabilize the position of the spray pipe, thereby ensuring that the punch 5 accurately passes through the wall of the spray pipe without deviation or distortion.

The above description is only a preferred specific implementation manner of the present invention, but the protection scope of the present invention is not limited thereto. Any technician familiar with the technical field can make equivalent replacements or changes according to the technical scheme and inventive concept of the present invention within the technical scope disclosed by the present invention, which should be covered by the protection scope of the present invention.

Claims (7)

1. A processing device for a cooling tower splash device, comprising a device body (1), a U-shaped frame (2) is fixed on the top of the device body (1), a hydraulic cylinder (4) is fixed on the top of the U-shaped frame (2), a punch (5) is fixed on the bottom of the telescopic end of the hydraulic cylinder (4), and the device body (1) is characterized in that: a curved panel (3) is fixed on the top of the device body (1), an electric control fixture (10) is fixed on the front and rear sides of the curved panel (3), an L-shaped curved slide plate (8) is installed laterally and slidably below the curved panel (3), and the device body (1) is fixed to the top of the device body (1). ) is fixed to the top right side of the L-shaped curved slide (8), a threaded rod (12) is rotatably mounted inside the circular frame (9), and the threaded rod (12) is driven by a motor, the threaded rod (12) is externally threadedly connected to a threaded block (11), and the threaded block (11) is slidably mounted inside the circular frame (9), a horizontal column (13) is fixed to the left side of the threaded block (11), a long groove (81) for sliding the horizontal column (13) is provided on the outer wall of the L-shaped curved slide (8), a groove (131) is provided on the top left side of the horizontal column (13), and a through-hole spring plate (14) is fixed above the inner wall of the groove (131) of the horizontal column (13); A resisting wheel (15) is rotatably mounted on the left end of the transverse column (13), and a cam wheel (16) is fixed to the front and rear sides of the rotating shaft of the resisting wheel (15). A knocking column (19) is penetrated and slidably mounted on the bottom of the inner wall of the groove (131) of the transverse column (13), and a spring is arranged between the knocking column (19) and the bottom of the inner wall of the groove (131) of the transverse column (13). The top of the knocking column (19) contacts the bottom of the through-hole spring plate (14), and a connecting plate (18) is fixed to the bottom of the knocking column (19), and two L-shaped rods (17) are fixed to the left side of the connecting plate (18). 2. A processing equipment for a cooling tower splashing device according to claim 1, characterized in that: a semi-arc protrusion is fixed to the outside of the protrusion wheel (16), and the end of the L-shaped rod (17) away from the connecting plate (18) is arranged in a semi-arc shape, and the semi-arc shape of the L-shaped rod (17) is located on the semi-arc protrusion movement trajectory of the protrusion wheel (16). 3. A processing equipment for a cooling tower splash device according to claim 2, characterized in that: the outer portion of the horizontal column (13) is sleeved with an internal grinding device (6), the internal grinding device (6) comprises a slider (61), a spiral groove sleeve (62), a telescopic ring (63), and two grinding brushes (64), the slider (61) is slidably mounted on the right outer wall of the L-shaped curved slide plate (8), the right outer portion of the horizontal column (13) is provided with an annular groove (132), the spiral groove sleeve (62) The spiral groove sleeve (62) is rotatably mounted on the right side of the annular groove (132) of the horizontal column (13), the spiral groove sleeve (62) passes through the slider (61), and a protrusion for slidingly mounting inside the spiral groove of the spiral groove sleeve (62) is fixed inside the slider (61), the fixed end of the telescopic ring (63) is fixed on the left side of the spiral groove sleeve (62), and the telescopic ring (63) is sleeved on the outside of the annular groove (132) of the horizontal column (13), and the two grinding brushes (64) are fixed on the outside of the telescopic ring (63). 4. A processing equipment for a cooling tower splash device according to claim 3, characterized in that: the internal grinding device (6) comprises a semicircular block 1 (65) and a plurality of semicircular blocks 2 (66), the semicircular block 1 (65) is fixed at the left edge of the telescopic end of the telescopic ring (63), and the plurality of semicircular blocks 2 (66) are evenly and equidistantly fixed on the left side of the inner wall of the annular groove (132) of the horizontal column (13). 5. A processing equipment for a cooling tower splashing device according to claim 4, characterized in that the semicircular surfaces of the semicircular block 2 (66) and the semicircular surface of the semicircular block 1 (65) are arranged opposite to each other, and the semicircular surface of the semicircular block 2 (66) is located on the movement trajectory of the semicircular surface of the semicircular block 1 (65). 6. A processing equipment for a cooling tower splashing device according to claim 5, characterized in that: a stabilizing device (7) is provided on both sides below the telescopic end of the hydraulic cylinder (4), and the stabilizing device (7) comprises an elastic telescopic rod (71) and a suction cup (72), the elastic telescopic rod (71) is fixed to the bottom of the telescopic end of the hydraulic cylinder (4), and the suction cup (72) is hinged to the bottom of the telescopic end of the elastic telescopic rod (71). 7. A processing equipment for a cooling tower splashing device according to claim 6, characterized in that: the stabilizing device (7) also includes an L-shaped push rod (73), an air pipe (74), a fixed plate (75), and a folding bag (76), wherein the fixed plate (75) is fixed to the outer wall of the fixed end of the elastic telescopic rod (71), and the folding bag (76) is fixed to the top of the fixed plate (75), one end of the L-shaped push rod (73) is fixed to the outer wall of the telescopic end of the elastic telescopic rod (71), the other end of the L-shaped push rod (73) is fixed to the top of the inner wall of the folding bag (76), and the other end of the L-shaped push rod (73) passes through the fixed plate (75), one end of the air pipe (74) is embedded in the bottom of the fixed plate (75), and the other end of the air pipe (74) is embedded in the outer wall of the suction cup (72).