CN114199708A - Device for testing abrasion resistance of pipe cleaner leather cup - Google Patents

Abstract

The invention discloses a device for testing the wear resistance of a pipe cleaner cup, which comprises: the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline; a link member having one side connected with the pig; a transmission member fixed to the other side of the device and connected to the other side of the link member; the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate; and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion. The technical problem that in the prior art, instrument and equipment for efficiently and accurately testing the wear resistance of the leather cup is lacked, so that scientific data support is lacked during material selection in leather cup processing is solved.

Description

Device for testing abrasion resistance of pipe cleaner leather cup

Technical Field

The invention relates to the field of pipe cleaners, in particular to a device for testing the wear resistance of a pipe cleaner leather cup.

Background

The pig is a special tool which is pushed by gas, liquid or a pipeline conveying medium and is used for cleaning the pipeline. The electromagnetic tracking system can be carried with an electromagnetic transmitting device to form an electronic tracking system together with a ground receiving instrument, and can be provided with other matched accessories to complete various complex pipeline operation tasks. In the process of cleaning the long-distance pipeline, the leather cup type pipe cleaner is widely used, and compared with other pipe cleaning facilities, the cleaning effect of the leather cup type pipe cleaner is better. But in the application of engineering sites, the leather cup of the leather cup type pipe cleaner is sometimes abraded greatly, and the evaluation of the wear resistance of the leather cup of the pipe cleaner has important significance for engineering practice.

However, the present inventors have found that the above prior art has at least the following technical problems:

lack the instrument and equipment that carry out high efficiency, accurate test to leather cup wear resistance, lack the problem of scientific data support when leading to leather cup processing material selection.

Disclosure of Invention

The embodiment of the invention provides a device for testing the wear resistance of a pipe cleaner cup, and solves the technical problem that in the prior art, instrument equipment for efficiently and accurately testing the wear resistance of the cup is lacked, so that scientific data support is lacked when the cup is processed and selected. The efficient and accurate device for testing the wear resistance of the pipe cleaner cup is achieved, the wear resistance of the pipe cleaner cup is tested, the advantages and disadvantages of the wear resistance of different materials are confirmed, and the technical effect of the optimal pipe cleaner design parameters is provided.

In order to solve the above problems, an embodiment of the present invention provides a device for testing the wear resistance of a pig cup. Wherein the apparatus comprises: the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline; a link member having one side connected with the pig; a transmission member fixed to the other side of the device and connected to the other side of the link member; the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate; and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion.

Preferably, the cylinder member includes:

an outer cylinder fixed to an outer layer of the cylinder member;

the first drainage port is arranged at the lower end of the outer cylinder and is positioned on one side of the lower end;

a second drain opening located on the other side of the lower end;

the oil inlet is arranged at the upper end of the outer barrel and is positioned on one side of the upper end;

a balancing port located on the other side of the upper end;

an inner cylinder detachably disposed in an inner layer of the cylinder member;

the positioning ring is fixed at the concentric position of the outer cylinder body and the inner cylinder body in a segmented manner;

a first axial location disposed on one side of the cylinder member;

a second axial location provided on the other side of the cylinder member.

Preferably, the link member includes:

the fixed connecting rod is arranged in the connecting rod component in a non-detachable mode, and one side of the fixed connecting rod is connected with the driving wheel;

one side of the first shaft is connected with the other side of the fixed connecting rod;

a secondary shaft connected to the other side of the primary shaft by a detachable bolt for rotating the drive wheel so that the pig is pushed out of the cylinder member.

Preferably, the power member includes:

the motor speed reducer is arranged on one side of the power component and is used for driving the speed reducer to operate through motor output;

and the coupler is arranged on the other side of the power member and is used for connecting the motor speed reducer with the transmission member.

Preferably, the transmission member includes:

the pinion shaft is arranged at the lower end of the transmission member and is connected with the coupler;

the large gear shaft is arranged in the middle of the transmission member, and the small gear shaft drives the large gear shaft to rotate;

the main driving wheel is arranged on one side of the transmission member, and the large gear shaft drives the main driving wheel to rotate through a shaft;

the auxiliary driving wheel is connected with the main driving wheel, and the main driving wheel drives the auxiliary driving wheel and the fixed connecting rod to move, wherein one end of the fixed connecting rod does circular motion, and the other end of the fixed connecting rod does linear reciprocating motion;

and the supporting seat is arranged at the lower end of the auxiliary driving wheel and is used for providing balance for the auxiliary driving wheel.

Preferably, the support member includes:

the guide rail is arranged in the supporting component and is used for supporting the fixed connecting rod to do linear reciprocating motion;

the supporting frame is fixedly arranged on two sides of the supporting component and used for providing supporting force for the supporting component.

One or more technical solutions provided in the embodiments of the present invention have at least the following technical effects or advantages:

the invention provides a device for testing the wear resistance of a pipe cleaner cup. Wherein the apparatus comprises: the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline; a link member having one side connected with the pig; a transmission member fixed to the other side of the device and connected to the other side of the link member; the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate; and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion.

The technical problem that in the prior art, instrument and equipment for efficiently and accurately testing the wear resistance of the leather cup is lacked, so that scientific data support is lacked during material selection in leather cup processing is solved. The efficient and accurate device for testing the wear resistance of the pipe cleaner cup is achieved, the wear resistance of the pipe cleaner cup is tested, the advantages and disadvantages of the wear resistance of different materials are confirmed, and the technical effect of the optimal pipe cleaner design parameters is provided.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the drawings needed for the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a device for testing the wear resistance of a pig cup according to an embodiment of the invention.

Fig. 2 is a schematic structural diagram of a device for testing the wear resistance of a pig cup according to an embodiment of the invention.

Fig. 3 is a schematic structural diagram of a device for testing the wear resistance of a pig cup according to an embodiment of the invention.

Description of reference numerals: the cylinder component 100, the outer cylinder 110, the first discharge outlet 111, the second discharge outlet 112, the oil inlet 113, the balance outlet 114, the inner cylinder 120, the positioning ring 130, the first axial positioning 140, the second axial positioning 150, the link component 200, the fixed link 210, the first shaft 220, the second shaft 230, the transmission component 300, the pinion shaft 310, the bull gear shaft 320, the primary drive wheel 330, the secondary drive wheel 340, the support base 341, the power component 400, the motor reducer 410, the coupling 420, the support component 500, the guide rail 510, and the support frame 520.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, specific embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous details are set forth to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the embodiments of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Technical idea

The invention provides a device for testing the wear resistance of a pipe cleaner cup, which solves the technical problem that in the prior art, no instrument and equipment for efficiently and accurately testing the wear resistance of the cup is available, so that scientific data support is unavailable when the cup is processed and selected.

In order to solve the technical problems, the technical scheme provided by the invention has the following general idea:

the technical scheme of the invention provides a device for testing the wear resistance of a pipe cleaner cup, wherein the device comprises: the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline; a link member having one side connected with the pig; a transmission member fixed to the other side of the device and connected to the other side of the link member; the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate; and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion. The efficient and accurate device for testing the wear resistance of the pipe cleaner cup is achieved, the wear resistance of the pipe cleaner cup is tested, the advantages and disadvantages of the wear resistance of different materials are confirmed, and the technical effect of the optimal pipe cleaner design parameters is provided.

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-3, an embodiment of the present invention provides a device for testing the wear resistance of a pig cup, wherein the device includes: a cylinder member 100, wherein the cylinder member 100 is fixed on one side of the device and is used for simulating the friction between the pipeline cleaner and the pipeline; a link member 200, one side of the link member 200 being connected with the pig; a transmission member 300 fixed to the other side of the device, the transmission member 300 being connected to the other side of the link member 200; the power member 400 is connected with the transmission member 300 through a coupler 420 and used for driving the gear to rotate; and a support member 500, the support member 500 being fixed to the lower end of the link member 200 for supporting the flexibility of the link in the linear motion.

Specifically, the overall structure of the device for testing the wear resistance of the pig leather cup can be divided into five parts, namely a cylinder body part 100, wherein the cylinder body part 100 is fixed on one side of the device and is a simulator for friction between a pig and a pipeline; a link part which is the link member 200, one side of the link member 200 being connected with the pig, which is a bridge connecting the pig with the rotating part; a transmission part which is the transmission member 300, the transmission member 300 is fixed on the other side of the device and is connected with the other side of the connecting rod member 200, the transmission member 300 comprises a plurality of groups of gears, and power and movement can be transmitted by a mechanical mode; the power part is the power member 400, the power member 400 is connected with the transmission member 300 through a coupler 420 and is used for driving a gear to rotate, and the power part comprises a motor, a speed reducer and the like and provides a power source for the wear resistance testing device; a support portion, which is the support member 500, the support member 500 being fixed to the lower end of the link member 200, such as: a support bracket, a guide rail, etc., and the support member 500 serves to support the flexibility of the link rod when it moves linearly. The cylinder body component 100, the connecting rod component 200, the transmission component 300, the power component 400 and the supporting component 500 form five parts of a wear resistance testing device, and a high-efficiency and accurate pipe cleaner leather cup wear resistance testing device is obtained, so that the wear resistance and tear resistance of a pipe cleaner leather cup are tested, the wear resistance and the wear resistance of different materials are determined, and the optimal pipe cleaner design parameters are provided.

Further, the cylinder block member 100 includes: an outer cylinder 110, the outer cylinder 110 being fixed to an outer layer of the cylinder member 100; a first drain port 111, wherein the first drain port 111 is disposed at a lower end of the outer cylinder 110 and is located at one side of the lower end; a second drain 112, the second drain 112 being located on the other side of the lower end; the oil inlet 113 is arranged at the upper end of the outer cylinder 110, and the oil inlet 113 is positioned at one side of the upper end; a balancing port 114, the balancing port 114 being located at the other side of the upper end; an inner cylinder 120, the inner cylinder 120 being detachably provided to an inner layer of the cylinder member 100; a positioning ring 130, wherein the positioning ring 130 is fixed at the concentric position of the outer cylinder 110 and the inner cylinder 120 in a segmented manner; a first axial location 140, the first axial location 140 being disposed on one side of the block member 100; a second axial location 150, the second axial location 150 being disposed on the other side of the cylinder member 100.

Specifically, the cylinder member is composed of an inner cylinder and an outer cylinder, the inner cylinder 120 is detachably installed to facilitate periodic replacement, and the outer cylinder 110 is fixedly installed. The inner cylinder 120 is fixed with the concentricity of the inner and outer bodies by the positioning ring 130, the positioning ring 130 is fixed at the concentricity of the outer cylinder 110 and the inner cylinder 120 in a segmented manner, and the two ends of the positioning ring 130 have axial positioning, which are the first axial positioning 140 and the second axial positioning 150 respectively. Two pipe orifices of the lower end of the outer cylinder body 110 are discharge orifices, namely a first discharge orifice 111 and a second discharge orifice 112, and are used for discharging waste liquid generated in the wear resistance test. One of two pipe orifices at the upper end of the outer cylinder body 110 is the oil inlet 113, and the other is the balance orifice 114. Because the positioning ring is a sectional type and provided with a channel, the pressure in the cylinder body component can be kept and the oil circuit can be kept smooth when the pipe cleaner reciprocates.

Further, the link member 200 includes: a fixed link 210, wherein the fixed link 210 is non-detachably disposed inside the link member 200, and one side of the fixed link 210 is connected to a driving wheel; a first shaft 220, one side of the first shaft 220 being connected to the other side of the fixed link 210; a second shaft 230, the second shaft 230 being connected to the other side of the first shaft 220 by a detachable bolt for rotating the transmission wheel so that the pig is pushed out of the cylinder member 100.

Specifically, the link member 200 is composed of the fixed link 210 and a shaft, the fixed link 210 connects the shaft with the transmission wheel, the fixed link 210 is not detachable, the fixed link 210 is disposed inside the link member 200, and one side of the fixed link 210 is connected with the transmission wheel. The shaft for connecting the pipe cleaner is divided into two parts, namely the first shaft 220 and the second shaft 230, which are connected by bolts and can be disassembled and disconnected, and the middle part is connected with a shaft, so that the pipe cleaner can be pushed out of the cylinder body by rotating the transmission wheel, and the pipe cleaner can be replaced conveniently.

Further, the power member 400 includes: the motor speed reducer 410 is arranged on one side of the power component 400, and is used for driving the speed reducer to operate through motor output; and a coupling 420, wherein the coupling 420 is disposed at the other side of the power member, and is used for connecting the motor reducer 410 with the transmission member 300.

Specifically, the power member 400 provides power for the pig cup wear resistance testing device, and the motor reducer 410 and the coupler 420 can meet the power, the rotating speed and the like required by the device in operation. The motor reducer 410 is an integrated body of a reducer and a motor, and the reducer is driven to operate through the output of the motor when the motor reducer works, so that the design can be simplified, and the space can be saved. The coupling is a device for coupling two shafts or a shaft and a rotating member, and rotates together in the process of transmitting motion and power, and the coupling 420 is used for connecting the motor reducer 410 and the transmission member 300 to play a role in connection. The use of the motor reducer in the power component can save space for the pipe cleaner cup wear resistance testing device and increase designability.

Further, the transmission member 300 includes: a pinion shaft 310, the pinion shaft 310 being disposed at a lower end of the driving member 300 and connected to the coupling 420; a large gear shaft 320, wherein the large gear shaft 320 is arranged in the middle of the transmission member 300, and the small gear shaft 310 drives the large gear shaft 320 to rotate; the main transmission wheel 330, the main transmission wheel 330 is arranged at one side of the transmission member 300, and the main transmission wheel 330 is driven to rotate by the large gear shaft 320 through a shaft; the auxiliary driving wheel 340, the auxiliary driving wheel 340 is connected with the main driving wheel 330, and the main driving wheel 330 drives the auxiliary driving wheel 320 and the fixed connecting rod 210 to move, wherein one end of the fixed connecting rod 210 makes a circular motion, and the other end makes a linear reciprocating motion; and the supporting seat 341 is disposed at the lower end of the auxiliary driving wheel 340, and is used for providing balance for the auxiliary driving wheel 320.

Specifically, the driving member 300 is composed of a gear box, a gear shaft, a bearing, a main driving wheel, a sub driving wheel, and the like. A large number of gears are integrated in the gear box and used for transmission, and an oil filling hole is formed in the top of the gear box and used for filling lubricating oil to the gear hole. The gear shaft is composed of the pinion shaft 310 and the pinion shaft 320, the pinion shaft 310 is arranged at the lower end of the transmission member 300 and is connected with the coupler 420, the pinion shaft 310 drives the pinion shaft 320 to rotate, and the pinion shaft 320 is arranged at the middle part of the transmission member 300. And, the main transmission wheel 330 is driven to rotate by the large gear shaft 320. The auxiliary transmission wheel 340 and the support base 341 can ensure the transmission balance of the connecting rod. The power of the power component can be transmitted to other working components through the transmission component, and the function of power transmission is achieved.

Further, the support member 500 includes: a guide rail 510, the guide rail 510 being disposed inside the support member 500, for supporting the fixed link 210 to make a linear reciprocating motion; the supporting frames 520 are fixedly arranged at two sides of the supporting member 500, and are used for providing supporting force for the supporting member 500.

Specifically, the supporting member 500 provides a supporting force for the device, and is composed of the guide rail 510 and the supporting bracket 520. The guide rail 510 is disposed inside the supporting member 500, and is used for supporting the fixed link 210 to make a linear reciprocating motion, and the supporting frame 520 is fixedly disposed at two sides of the supporting member 500, and is used for providing a supporting force for the supporting member 500. The good support can ensure the flexibility, the precision and the stability of the connecting rod when the connecting rod moves linearly.

Example 2

In order to explain the technical scheme of the device for testing the wear resistance of the pipe cleaner cup more clearly, the embodiment of the application provides a using method of the device for testing the wear resistance of the pipe cleaner cup, which comprises the following steps:

when the device is used, the power component 400 provides power for the device for testing the wear resistance of the pipe cleaner leather cup, wherein the motor output of the motor reducer 410 drives the reducer, the reducer is transmitted to the pinion shaft 310 through the coupler 420, the pinion drives the gearwheel to rotate, the gearwheel drives the main driving wheel 330 to rotate through the pinion shaft 320, the main driving wheel 330 drives the auxiliary driving wheel 340 and the fixed connecting rod 210 to move, one end of the fixed connecting rod 210 performs circular motion, the other end of the fixed connecting rod is connected with the shaft of the pipe cleaner to perform linear reciprocating motion, and therefore the pipe cleaner performs reciprocating motion at a certain speed in the cylinder body, and the wear resistance and the tear resistance of the pipe cleaner leather cup are tested.

The technical scheme provided by the invention at least has the following technical effects or advantages:

the invention provides a device for testing the wear resistance of a pig leather cup, wherein the device comprises: the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline; a link member having one side connected with the pig; a transmission member fixed to the other side of the device and connected to the other side of the link member; the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate; and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion. The efficient and accurate device for testing the wear resistance of the pipe cleaner cup is achieved, the wear resistance of the pipe cleaner cup is tested, the advantages and disadvantages of the wear resistance of different materials are confirmed, and the technical effect of the optimal pipe cleaner design parameters is provided.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the embodiments of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (6)

1. A pig cup wear resistance testing device, wherein the device comprises:

the cylinder component is fixed on one side of the device and is used for simulating the friction between the pipe cleaner and the pipeline;

a link member having one side connected with the pig;

a transmission member fixed to the other side of the device and connected to the other side of the link member;

the power component is connected with the transmission component through a coupler and is used for driving the gear to rotate;

and the supporting member is fixed at the lower end of the connecting rod member and is used for supporting the flexibility of the connecting rod during linear motion.

2. The pig cup wear resistance testing device of claim 1, wherein the cylinder block member comprises:

an outer cylinder fixed to an outer layer of the cylinder member;

the first drainage port is arranged at the lower end of the outer cylinder and is positioned on one side of the lower end;

a second drain opening located on the other side of the lower end;

the oil inlet is arranged at the upper end of the outer barrel and is positioned on one side of the upper end;

a balancing port located on the other side of the upper end;

an inner cylinder detachably disposed in an inner layer of the cylinder member;

the positioning ring is fixed at the concentric position of the outer cylinder body and the inner cylinder body in a segmented manner;

a first axial location disposed on one side of the cylinder member;

a second axial location provided on the other side of the cylinder member.

3. The pig cup wear resistance testing device of claim 1, wherein the link member comprises:

the fixed connecting rod is arranged in the connecting rod component in a non-detachable mode, and one side of the fixed connecting rod is connected with the driving wheel;

one side of the first shaft is connected with the other side of the fixed connecting rod;

a secondary shaft connected to the other side of the primary shaft by a detachable bolt for rotating the drive wheel so that the pig is pushed out of the cylinder member.

4. The pig cup wear resistance testing device of claim 1, wherein the power component comprises:

the motor speed reducer is arranged on one side of the power component and is used for driving the speed reducer to operate through motor output;

and the coupler is arranged on the other side of the power member and is used for connecting the motor speed reducer with the transmission member.

5. The pig cup wear resistance testing device of claim 1, wherein the transmission member comprises:

the pinion shaft is arranged at the lower end of the transmission member and is connected with the coupler;

the large gear shaft is arranged in the middle of the transmission member, and the small gear shaft drives the large gear shaft to rotate;

the main driving wheel is arranged on one side of the transmission member, and the large gear shaft drives the main driving wheel to rotate through a shaft;

the auxiliary driving wheel is connected with the main driving wheel, and the main driving wheel drives the auxiliary driving wheel and the fixed connecting rod to move, wherein one end of the fixed connecting rod does circular motion, and the other end of the fixed connecting rod does linear reciprocating motion;

and the supporting seat is arranged at the lower end of the auxiliary driving wheel and is used for providing balance for the auxiliary driving wheel.

6. The pig cup wear resistance testing device of claim 1, wherein the support member comprises:

the guide rail is arranged in the supporting component and is used for supporting the fixed connecting rod to do linear reciprocating motion;

the supporting frame is fixedly arranged on two sides of the supporting component and used for providing supporting force for the supporting component.

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