CN216574249U - Bearing machining device with function of measuring precision - Google Patents

Abstract

The utility model provides a bearing processing device with the function of measuring precision, which relates to the technical field of measuring precision and comprises a workbench; an electrical box is installed on one side of the top of the workbench, a PLC and a circuit breaker are installed in the electrical box, the PLC is connected with a circuit of the circuit breaker, and a defective product port A and a defective product port B are formed in one side of the workbench; control solenoid valve B through the PLC controller and receive electricity, solenoid valve B drives cylinder B action after receiving electricity, cylinder B drives manipulator B action and presss from both sides the outer lane of awaiting measuring the bearing, range finding sensor A detects the distance between manipulator B and the manipulator E at this in-process, then signals gives the PLC controller, the PLC controller judges whether qualified bearing outer diameter, reach the purpose that mechanical automation detected the product external diameter, solve the last outgoing detection of bearing processing and often omit or rely on the manual detection of measurement personnel, and the manual detection often the more problem of human influence factor.

Description

Bearing machining device with function of measuring precision

Technical Field

The utility model belongs to the technical field of measurement accuracy, more specifically say, in particular to bearing processingequipment of measurement accuracy function.

Background

The bearing is an important part in the modern mechanical equipment, and the main function of the bearing is to support a mechanical rotating body, reduce the friction coefficient in the movement process of the mechanical rotating body and ensure the rotation precision of the mechanical rotating body.

Based on the above, the inventor finds that along with the gradual improvement of the requirement of market users on the equipment installation precision, the requirement on high-precision bearings can be increased, the bearing manufacturers can guarantee the product quality by only depending on the processing quality in many times in the past, the final factory detection is usually omitted or the manual detection by detection personnel is usually carried out, and the manual detection is usually carried out by a plurality of human influence factors.

In view of the above, it is an object of the present invention to provide a bearing machining apparatus that improves the conventional structure and defects and has a function of measuring accuracy, so as to achieve a more practical purpose.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a bearing processingequipment of measurement accuracy function to solve the last outgoing inspection of current bearing processing and often omit or rely on the manual detection of measurement personnel, and the manual detection often is the more problem of human influence factor.

The utility model discloses measurement accuracy's measurement accuracy equipment's purpose and efficiency are reached by following specific technological means:

the bearing processing device with the function of measuring the precision comprises a workbench; an electric box is installed on one side of the top of the workbench, a PLC (programmable logic controller) and a circuit breaker are installed in the electric box, the PLC is connected with a circuit of the circuit breaker, a defective product port A and a defective product port B are formed in one side of the workbench, two circular holes are formed in the workbench, a push block F and a push block G are installed in the circular holes of the workbench respectively, the other ends of the push block F and the push block G are fixedly connected with the workbench, and a measurement inlet is formed in the other side of the workbench; the arm, the arm is the U-shaped, and the arm is connected with cylinder A's both ends homogeneous phase, and solenoid valve A is installed at cylinder A top, solenoid valve A line connection PLC controller, and solenoid valve A's other end line connection cylinder A, arm bottom are connected with cylinder B, cylinder C and cylinder D and cylinder E, another bottom fixed connection workstation top of arm.

Further, cylinder B is connected with manipulator B top, and solenoid valve B is installed at cylinder B top, and solenoid valve B line connection PLC controller, solenoid valve B's other end line connection cylinder B, and manipulator B top installs range sensor A, and range sensor A line connection PLC controller, cylinder D are connected with manipulator D top, and solenoid valve D is installed at cylinder D top, and solenoid valve D line connection PLC controller solenoid valve D's other end line connection cylinder D.

Further, cylinder C manipulator C top with be connected, solenoid valve C is installed at cylinder C top, solenoid valve C line connection PLC controller, solenoid valve C's other end line connection cylinder C, and range sensor C is installed at manipulator C top, and range sensor C line connection PLC controller, cylinder E is connected with manipulator E top, solenoid valve E is installed to cylinder E, solenoid valve line connection PLC controller, solenoid valve E's other end line connection cylinder E.

Furthermore, a distance measuring sensor G is installed above a measuring inlet of the workbench and is connected with the PLC through a line.

Furthermore, the rear end of the push block F is connected with a cylinder F, an electromagnetic valve F is installed at the top of the cylinder F, the electromagnetic valve F is connected with a PLC controller through a circuit, and the other end of the electromagnetic valve F is connected with the cylinder F through a circuit.

Furthermore, the rear end of the push block G is connected with a cylinder G, an electromagnetic valve G is installed at the top of the cylinder G and is connected with a PLC controller through a circuit, and the other end of the electromagnetic valve G is connected with the cylinder G through a circuit.

Compared with the prior art, the utility model discloses following beneficial effect has:

distance measuring sensor A's setting, it gets electricity through PLC controller control solenoid valve B, solenoid valve B gets electricity and drives cylinder B action after the electricity, cylinder B drives manipulator B action and cliies the outer lane of awaiting measuring the bearing, distance measuring sensor A detects the distance between manipulator B and the manipulator E at this in-process, then signals gives the PLC controller, the PLC controller judges whether qualified bearing external diameter, cooperation distance measuring sensor B's setting simultaneously gets electricity through PLC controller control solenoid valve C, solenoid valve C gets electricity and drives cylinder C action, cylinder C drives manipulator C action and cliies the inner circle of awaiting measuring the bearing, distance measuring sensor C detects the distance between manipulator C and the manipulator D at this in-process, then signals gives the PLC controller, the PLC controller judges whether qualified bearing internal diameter.

The arrangement of the distance measuring sensor G is characterized in that the distance measuring sensor G detects the thickness of a bearing from the upper side when the bearing to be measured enters the workbench from a measuring inlet, and meanwhile, the arrangement of the push block F and the push block G is matched, the push block F and the push block G can push the bearing which is measured unqualified into the defective product port A and the defective product port B, so that the unqualified product and the qualified product are distinguished, the purpose of mechanically and automatically detecting the outer diameter, the inner diameter and the thickness of the product is achieved, and the problem that manual detection is frequently carried out due to the fact that factory detection at the last time of bearing processing is often omitted or manual detection is often carried out by detection personnel is solved.

Drawings

Fig. 1 is a schematic axial view of the present invention;

fig. 2 is a schematic view of the mechanical arm and mechanical arm combination of the present invention;

FIG. 3 is a schematic axial view of the push block of the present invention;

fig. 4 is a schematic view of the distance measuring sensor G of the present invention;

fig. 5 is an axial view of the inside of the electrical box of the present invention;

fig. 6 is a schematic view of the measurement process of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a work table; 101. an electric box; 102. a defective product port A; 103. a defective product port B; 104. a measurement inlet; 2. a mechanical arm; 201. a cylinder A; 2011. an electromagnetic valve A; 3. a manipulator B; 301. a cylinder B; 3011. a solenoid valve B; 302. a distance measuring sensor A; 4. a manipulator C; 401. a cylinder C; 4011. a solenoid valve C; 402. a distance measuring sensor C; 5. a manipulator D; 501. a cylinder D; 5011. an electromagnetic valve D; 6. a manipulator E; 601. a cylinder E; 6011. an electromagnetic valve E; 7. a push block F; 701. a cylinder F; 7011. a solenoid valve F; 8. a push block G; 801. a cylinder G; 8011. an electromagnetic valve G; 9. a distance measuring sensor G; 10. a PLC controller; 11. a circuit breaker.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 6:

the utility model provides a bearing processing device with the function of measuring precision, which comprises a workbench 1; an electric box 101 is installed on one side of the top of a workbench 1, a PLC controller 10 and a circuit breaker 11 are installed in the electric box 101, the PLC controller 10 is connected with the circuit breaker 11 through a line, a defective product port A102 and a defective product port B103 are arranged on one side of the workbench 1, two round holes are formed in the workbench 1, a push block F7 and a push block G8 are installed in the round holes of the workbench 1 respectively, the other ends of the push block F7 and the push block G8 are fixedly connected with the workbench 1, the rear end of the push block G8 is connected with a cylinder G801, an electromagnetic valve G8011 is installed on the top of the cylinder G801, the electromagnetic valve G8011 is connected with the PLC controller 10 through a line, the other end of the electromagnetic valve G8011 is connected with the cylinder G801 through a line, and a measurement inlet 104 is formed in the other side of the workbench 1; arm 2, arm 2 are the U-shaped, and arm 2 is connected with the both ends homogeneous phase of cylinder A201, and solenoid valve A2011 is installed at cylinder A201 top, and solenoid valve A2011 line connection PLC controller 10, other end line connection cylinder A201 of solenoid valve A2011, and arm 2 bottom is connected with cylinder B301, cylinder C401 and cylinder D501 and cylinder E601, another bottom fixed connection workstation 1 top of arm 2.

The cylinder B301 is connected with the top end of a manipulator B3, an electromagnetic valve B3011 is installed at the top of the cylinder B301, the electromagnetic valve B3011 is connected with a PLC (programmable logic controller) 10 through a line, the other end of the electromagnetic valve B3011 is connected with the cylinder B301 through a line, a ranging sensor A302 is installed at the top of a manipulator B3, the ranging sensor A302 is connected with the PLC 10 through a line, a cylinder D501 is connected with the top end of a manipulator D5, an electromagnetic valve D5011 is installed at the top of the cylinder D501, and the electromagnetic valve D5011 is connected with the other end of the PLC 10 through a line and connected with the cylinder D501;

by adopting the scheme, the PLC 10 controls the electromagnetic valve B3011 to be electrified, the electromagnetic valve B3011 drives the air cylinder B301 to act after being electrified, the air cylinder B301 drives the mechanical arm B3 to act to clamp the outer ring of the bearing to be measured, the distance measuring sensor A302 detects the distance between the mechanical arm B3 and the mechanical arm E6 in the process, then a signal is sent to the PLC 10, and the PLC 10 judges whether the outer diameter of the bearing is qualified or not.

The top end of a manipulator C4 of an air cylinder C401 is connected, an electromagnetic valve C4011 is installed at the top of the air cylinder C401, a line of the electromagnetic valve C4011 is connected with a PLC (programmable logic controller) 10, a line of the other end of the electromagnetic valve C4011 is connected with the air cylinder C401, a distance measuring sensor C402 is installed at the top of a manipulator C4, the line of the distance measuring sensor C402 is connected with the PLC 10, an air cylinder E601 is connected with the top end of a manipulator E6, an electromagnetic valve E6011 is installed on the air cylinder E601, a line of the electromagnetic valve E6011 is connected with the PLC 10, and a line of the other end of the electromagnetic valve E6011 is connected with the air cylinder E601;

adopt above-mentioned scheme, control solenoid valve C4011 through PLC controller 10 and receive the electricity, solenoid valve C4011 drives cylinder C401 action after receiving the electricity, and cylinder C401 drives manipulator C4 action and presss from both sides the inner circle of awaiting measuring the bearing, and range finding sensor C402 detects the distance between manipulator C4 and manipulator D5 at this in-process, then sends signal for PLC controller 10, and PLC controller 10 judges whether the bearing internal diameter is qualified.

A distance measuring sensor G9 is arranged above the measuring inlet 104 of the workbench 1, and a distance measuring sensor G9 is connected with the PLC controller 10 through a circuit;

with the above-described arrangement, the distance measuring sensor G9 detects the thickness of the bearing to be measured from above when the bearing enters the table 1 from the measurement inlet 104.

The rear end of the push block F7 is connected with a cylinder F701, the top of the cylinder F701 is provided with a solenoid valve F7011, the solenoid valve F7011 is in line connection with the PLC 10, and the line of the other end of the solenoid valve F7011 is connected with the cylinder F701;

by adopting the scheme, the push block F7 and the push block G8 can push the bearing which is measured unqualified into the defective product port A102 and the defective product port B103, so that the unqualified product can be distinguished from the qualified product.

The specific use mode and function of the embodiment are as follows:

in the utility model, when in use, a bearing to be detected is placed into the measuring inlet 104, after the bearing to be detected enters the workbench 1 from the measuring inlet 104, the distance measuring sensor G9 detects the thickness of the bearing from the upper side, the distance measuring sensor G9 transmits a detection result signal into the PLC controller 10, the PLC controller 10 judges whether the bearing is qualified, if the unqualified PLC controller 10 controls the electromagnetic valve G8011 to be electrified, the electromagnetic valve G8011 is electrified to drive the air cylinder G801, the air cylinder G801 pushes the push block G8 to push unqualified products into the defective product port B103, if the bearing is qualified, the PLC controller 10 controls the electromagnetic valve A2011 to be electrified, the electromagnetic valve A2011 drives the air cylinder A201 to act, the air cylinder A201 drives the mechanical arm 2 to act, the mechanical arm B3, the mechanical arm C4, the mechanical arm D5 and the mechanical arm E6 are sent to a detection position, then the PLC controller 10 controls the electromagnetic valve C4011 to be electrified, the electromagnetic valve C4011 drives the air cylinder C401 to act after the electromagnetic valve C4011 is electrified, the cylinder C401 drives the manipulator C4 to clamp the inner ring of the bearing to be measured, the distance measuring sensor C402 detects the distance between the manipulator C4 and the manipulator D5 in the process, then a signal is sent to the PLC 10, the PLC 10 judges whether the inner diameter of the bearing is qualified or not, meanwhile, the PLC 10 controls the electromagnetic valve B3011 to be electrified, the electromagnetic valve B3011 drives the cylinder B301 to act after being electrified, the cylinder B301 drives the manipulator B3 to clamp the outer ring of the bearing to be measured, the distance measuring sensor A302 detects the distance between the manipulator B3 and the manipulator E6 in the process, then a signal is sent to the PLC 10, the PLC 10 judges whether the outer diameter of the bearing is qualified or not, if the outer diameter of the bearing is unqualified in the step, the PLC 10 controls the electromagnetic valve F7011 to be electrified, the cylinder F7011 drives the cylinder F701 to drive the pushing block F7 to push the unqualified product into the defective port A102, and if the measurement is qualified, the problem of the final outgoing inspection of bearing processing often omit or rely on the manual detection of testing personnel, and manual detection often human influence factor is more is solved.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. Bearing processingequipment of measurement accuracy function, its characterized in that: comprises a workbench (1); an electric box (101) is installed on one side of the top of the workbench (1), a PLC (programmable logic controller) (10) and a circuit breaker (11) are installed in the electric box (101), the PLC (10) is in line connection with the circuit breaker (11), a defective product port A (102) and a defective product port B (103) are arranged on one side of the workbench (1), two round holes are formed in the workbench (1), a push block F (7) and a push block G (8) are installed in the round holes of the workbench (1) respectively, the other ends of the push block F (7) and the push block G (8) are fixedly connected with the workbench (1), and a measurement inlet (104) is formed in the other side of the workbench (1); arm (2), arm (2) are the U-shaped, and arm (2) are connected with the both ends homogeneous phase of cylinder A (201), and solenoid valve A (2011) are installed at cylinder A (201) top, and solenoid valve A (2011) line connection PLC controller (10), other end line connection cylinder A (201) of solenoid valve A (2011), and arm (2) bottom is connected with cylinder B (301), cylinder C (401) and cylinder D (501) and cylinder E (601), another bottom fixed connection workstation (1) top of arm (2).

2. The bearing machining apparatus with function of measuring accuracy according to claim 1, wherein: cylinder B (301) are connected with manipulator B (3) top, solenoid valve B (3011) are installed at cylinder B (301) top, solenoid valve B (3011) line connection PLC controller (10), cylinder B (301) are connected to the other end line of solenoid valve B (3011), and range sensor A (302) is installed at manipulator B (3) top, range sensor A (302) line connection PLC controller (10), cylinder D (501) are connected with manipulator D (5) top, solenoid valve D (5011) are installed at cylinder D (501) top, solenoid valve D (5011) line connection cylinder D (501) of the other end line connection of PLC controller (10) solenoid valve D (5011).

3. The bearing machining apparatus having a function of measuring accuracy according to claim 1, wherein: cylinder C (401) manipulator C (4) top with be connected, solenoid valve C (4011) is installed at cylinder C (401) top, PLC controller (10) is connected to solenoid valve C (4011) line, cylinder C (401) is connected to the other end line of solenoid valve C (4011), and range sensor C (402) is installed at manipulator C (4) top, PLC controller (10) is connected to range sensor C (402) line, cylinder E (601) is connected with manipulator E (6) top, solenoid valve E (6011) is installed to cylinder E (601), PLC controller (10) is connected to solenoid valve E (6011) line, cylinder E (601) is connected to the other end line of solenoid valve E (6011).

4. The bearing machining apparatus with function of measuring accuracy according to claim 1, wherein: and a distance measuring sensor G (9) is installed above a measuring inlet (104) of the workbench (1), and the distance measuring sensor G (9) is connected with a PLC (programmable logic controller) controller (10) through a line.

5. The bearing machining apparatus with function of measuring accuracy according to claim 1, wherein: the rear end of the push block F (7) is connected with a cylinder F (701), an electromagnetic valve F (7011) is installed at the top of the cylinder F (701), the electromagnetic valve F (7011) is in line connection with the PLC (10), and the other end of the electromagnetic valve F (7011) is in line connection with the cylinder F (701).

6. The bearing machining apparatus with function of measuring accuracy according to claim 1, wherein: the rear end of the push block G (8) is connected with a cylinder G (801), an electromagnetic valve G (8011) is installed at the top of the cylinder G (801), the electromagnetic valve G (8011) is in line connection with the PLC (10), and the other end of the electromagnetic valve G (8011) is in line connection with the cylinder G (801).

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