CN218211718U - Mandrel spring elasticity testing device - Google Patents

Abstract

The utility model discloses a dabber spring force testing arrangement belongs to dabber detection technology field, including dabber, support frame, set up elevating system A on the support frame and set up the detector on elevating system A, elevating system A is used for adjusting the height of detector, the detector is used for carrying out the part detection to the dabber of below, the detector comprises device seat, probe switch A, two probe switch B, probe switch A, probe switch B pass the device seat respectively, and probe switch A all is located the bottom of device seat with probe switch B's detecting head, the spindle is provided with locking piece and omega spring. The utility model discloses, can carry out elasticity test to the dabber automatically, can also detect the installation of spindle lock piece and omega spring.

Description

Mandrel spring elasticity testing device

Technical Field

The utility model relates to a dabber detects technical field, in particular to dabber spring force testing arrangement.

Background

The spindle is an important component of the automobile safety belt, and in order to ensure that the spring elasticity quality of each spindle reaches the standard, a corresponding elasticity test needs to be carried out on the spring in the production process;

at present, equipment for automatically detecting the elasticity of a mandrel spring is lacked, the relevant elasticity test of the mandrel still needs workshop staff to manually detect one by one, and the locking block and the omega spring which are installed on the mandrel cannot be automatically detected, so that the detection is not convenient enough.

SUMMERY OF THE UTILITY MODEL

The present invention provides a device for testing the elasticity of a spindle spring in order to solve the above-mentioned problems.

In order to achieve the above purpose, the utility model adopts the technical proposal that:

the utility model provides a dabber spring elasticity testing arrangement, includes dabber, support frame, sets up elevating system A on the support frame and sets up the detector on elevating system A, elevating system A is used for adjusting the height of detector, the detector is used for carrying out the part to the dabber of below and detects.

The detector is further characterized by comprising a device seat, a probe switch A and two probe switches B, wherein the probe switch A and the probe switch B respectively penetrate through the device seat, and detection heads of the probe switch A and the probe switch B are both positioned at the bottom of the device seat.

The spindle is further provided with a locking block and an omega spring.

The detection device is characterized in that the probe switch A is used for detecting a locking block, and the two probe switches B are used for detecting omega springs.

Further, the lifting mechanism a is an electric slide rail, and a driving end of the electric slide rail can be used for adjusting the height of the detector.

The support frame is further provided with a clamping tool, and the clamping tool is used for clamping the mandrel and moving the mandrel in position.

The clamping tool comprises an assembly seat, a first sliding rail, a bottom plate, a cylinder A, a second sliding rail, an electric sliding rail A, a cylinder B, a transferring table and a mechanical claw, wherein the assembly seat is installed on the bottom plate through the first sliding rail, the bottom plate is installed on the support frame through the second sliding rail, the driving end of the cylinder A is connected with the rear end of the assembly seat, the driving end of the electric sliding rail A is connected with the bottom plate, the cylinder B is fixedly installed on the assembly seat, the driving end of the cylinder B is connected with the transferring table, the transferring table is liftable and movably installed with the assembly seat, and the mechanical claw is installed on the transferring table.

The lifting mechanism B is composed of a bearing arm, a cylinder C and an electric sliding rail B, the cylinder C and the bearing arm are installed, and the driving ends of the electric sliding rail B and the cylinder C are connected with a part platform.

The part bench is provided with a testing mechanism, the testing mechanism comprises a detection bench, an electric slide rail C and a pressure sensor, the telescopic end of the electric slide rail C is provided with the pressure sensor, and the surface of the detection bench is provided with a mandrel port.

The support frame is further provided with three mandrel tables, and the mandrel tables are provided with mandrel grooves for placing mandrels.

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

the utility model discloses, can carry out elasticity test to the dabber automatically, can also detect the installation of spindle lock piece and omega spring.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a rear view of the present invention.

Fig. 3 is a top view of the present invention.

Fig. 4 is a schematic view of the testing mechanism of the present invention.

Fig. 5 is a partial enlarged view of the present invention.

Fig. 6 is a bottom view of the device seat of the present invention.

Fig. 7 is a schematic view of the electric slide rail a of the present invention.

In the figure: 101. a lifting mechanism A; 103. a device seat; 104. a support frame; 105. assembling a seat; 106. an electric slide rail A; 107. a gripper; 108. a load-bearing arm; 109. a cylinder C; 110. a part table; 111. a testing mechanism; 112. a probe switch A; 113. a probe switch B; 114. a mandrel; 115. omega springs; 116. a locking block; 201. a first slide rail; 202. a base plate; 203. a cylinder A; 204. a second slide rail; 301. a cylinder B; 302. moving the table; 401. an electric slide rail B; 6. a detection table; 7. an electric slide rail C; 8. a pressure sensor.

Detailed Description

In order to make the utility model realize the technical means, the creation characteristics, the achievement are that purpose and efficiency are easily understood and known, combine the detailed implementation mode below, further explain the utility model.

Referring to as shown in fig. 1 and 5, the embodiment of the utility model provides a mandrel spring elasticity testing arrangement, including dabber 114, support frame 104, set up elevating system A101 on support frame 104 and set up the detector on elevating system A101, elevating system A101 is electronic slide rail, and elevating system A101 is used for adjusting the height of detector, and when elevating system A101 adjusted the detector and descends, the detector carried out the part detection to the dabber 114 of below.

Referring to fig. 5 and 6, the detector is composed of a device base 103, a probe switch a112, and two probe switches B113, the probe switch a112 and the probe switch B113 respectively pass through the device base 103, and the probe heads of the probe switch a112 and the probe switch B113 are both located at the bottom of the device base 103, a locking block 116 and an omega spring 115 are arranged on a mandrel 114, one end of the omega spring 115 is sleeved at the protruding part of the locking block 116 to form an elastic component, the probe switch a112 is used for detecting the locking block 116, specifically, when the probe switch a112 contacts the protruding part on the locking block 116, it indicates that the locking block 116 is normally installed, and when the protruding part on the locking block 116 does not correspond to the position of the probe switch a112, no contact occurs, thereby completing the installation detection of the locking block 116;

the two probe switches B113 are configured to detect the omega spring 115, specifically, the two probe switches B113 are disposed according to a curved track of the omega spring 115 below, and the end of the probe switch B113 has a notch, that is, when the omega spring 115 is normally installed and the probe switch B113 descends, the omega spring 115 is just located in the notch and does not contact with the probe switch B113, and when the omega spring 115 is abnormally installed and dislocated, the omega spring 115 contacts with the probe switch B113, so that the abnormal installation of the omega spring 115 is detected.

Referring to fig. 1, 2, 3, and 7, a supporting frame 104 is provided with a clamping tool, the clamping tool is used for clamping the mandrel 114 and moving the position of the mandrel 114, the clamping tool includes an assembly base 105, a first slide rail 201, a bottom plate 202, a cylinder a203, a second slide rail 204, an electric slide rail a106, a cylinder B301, a maneuvering table 302, and a gripper 107, the assembly base 105 is mounted with the bottom plate 202 through the first slide rail 201, the bottom plate 202 is mounted with the supporting frame 104 through the second slide rail 204, a driving end of the cylinder a203 is connected with a rear end of the assembly base 105, a driving end of the electric slide rail a106 is connected with the bottom plate 202, the cylinder B301 is fixedly mounted on the assembly base 105, and a driving end of the cylinder B301 is connected with the maneuvering table 302, the maneuvering table 302 is movably mounted with the assembly base 105 in a liftable manner, the gripper 107 is mounted on the maneuvering table 302, three mandrel tables are provided on the supporting frame 104, and mandrel grooves are provided on the mandrel tables for placing the mandrel 114;

a lifting mechanism B is arranged on one side of the support frame 104 and is installed with a machine tool, the lifting mechanism B consists of a bearing arm 108, a cylinder C109 and an electric sliding rail B401, the electric sliding rail B401 and the cylinder C109 are installed with the bearing arm 108, and the driving ends of the electric sliding rail B401 and the cylinder C109 are connected with a part table 110;

as shown in fig. 4, a testing mechanism 111 is arranged on the part table 110, the testing mechanism 111 includes a detection table 6, an electric slide rail C7 and a pressure sensor 8, the pressure sensor 8 is arranged at the telescopic end of the electric slide rail C7, a mandrel port is formed on the surface of the detection table 6, and the detection table 6 is fixedly connected with the part table 110;

specifically, the electric slide rail a106 adjusts the bottom plate 202 to move on the slide rail two 204 to the position of the mandrel below the device seat 103, after the position is reached, the air cylinder a203 controls the assembly seat 105 to move on the slide rail one 201 on the bottom plate 202, then the air cylinder B301 and the transfer table 302 adjust the height of the mechanical claw 107, the mechanical claw 107 grips the mandrel, the mandrel 114 is reset to be placed on the mandrel table, namely below the testing mechanism 111, the lifting mechanism B adjusts the testing mechanism 111 to descend through the device table 110, and the testing mechanism 111 detects the elastic force of the mandrel 114;

the elasticity detection specifically comprises the following steps: when the detection table 6 descends, the upper end of the mandrel 114 is located in a mandrel port, the mandrel port has a fixing effect on the mandrel 114, the telescopic end of the electric sliding rail C7 extends, the pressure sensor 8 acts on the protruding portion of the locking block 116 during extension, the electric sliding rail C7 performs three telescopic operations, so that a three-time feedback value of the locking block 116 is measured, and the test content is fed back to the monitoring table, after the test is completed, the testing mechanism 111 rises, the bottom plate 202 moves to the mandrel position below the device seat 103 again, because the clamping tool comprises the two mechanical claws 107, the mandrels below the device seat 103 and the mandrels below the testing mechanism 111 can be clamped simultaneously, after the clamping tool resets, the mandrels below the device seat 103 can be moved to the testing mechanism 111, the mandrels below the testing mechanism 111 move to the mandrel table located at the rightmost side in fig. 1, the mandrels located at the rightmost side are subjected to labeling by the labeling machine finally, and then are loaded into the storage basket.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art will be able to make the description as a whole, and the embodiments may be combined as appropriate to form other embodiments as will be apparent to those skilled in the art.

Claims (10)

1. The device for testing the elasticity of the mandrel spring is characterized by comprising a mandrel (114), a support frame (104), a lifting mechanism A (101) arranged on the support frame (104) and a detector arranged on the lifting mechanism A (101), wherein the lifting mechanism A (101) is used for adjusting the height of the detector, and the detector is used for detecting components of the mandrel (114) below.

2. The apparatus for testing the elasticity of the spindle spring according to claim 1, wherein: the detector comprises device seat (103), probe switch A (112), two probe switch B (113), probe switch A (112), probe switch B (113) pass device seat (103) respectively, and probe switch A (112) and probe switch B (113) the detecting head all is located the bottom of device seat (103).

3. The mandrel spring force testing device according to any one of claims 1 or 2, wherein: the mandrel (114) is provided with a locking block (116) and an omega spring (115).

4. The mandrel spring force testing device according to claim 2, wherein: the probe switch A (112) is used for detecting a locking block (116), and the two probe switches B (113) are used for detecting omega springs (115).

5. The mandrel spring force testing device according to claim 1, wherein: elevating system A (101) are electronic slide rail, the drive end of electronic slide rail can be used to adjust the height of detector.

6. The mandrel spring force testing device according to claim 1, wherein: and a clamping tool is arranged on the support frame (104) and is used for clamping the mandrel (114) and moving the mandrel (114).

7. The mandrel spring force testing device of claim 6, wherein: the clamping tool comprises an assembling seat (105), a first sliding rail (201), a bottom plate (202), a cylinder A (203), a second sliding rail (204), an electric sliding rail A (106), a cylinder B (301), a transferring table (302) and a mechanical claw (107), wherein the assembling seat (105) is installed with the bottom plate (202) through the first sliding rail (201), the bottom plate (202) is installed with a supporting frame (104) through the second sliding rail (204), the driving end of the cylinder A (203) is connected with the rear end of the assembling seat (105), the driving end of the electric sliding rail A (106) is connected with the bottom plate (202), the cylinder B (301) is fixedly installed on the assembling seat (105), the driving end of the cylinder B (301) is connected with the transferring table (302), the transferring table (302) is liftable and movably installed with the assembling seat (105), and the mechanical claw (107) is installed on the transferring table (302).

8. The mandrel spring force testing device according to claim 1, wherein: and the lifting mechanism B is composed of a bearing arm (108), a cylinder C (109) and an electric sliding rail B (401), the cylinder C (109) and the bearing arm (108) are installed, and the driving ends of the electric sliding rail B (401) and the cylinder C (109) are connected with a part table (110).

9. The apparatus for testing elasticity of a spindle spring according to claim 8, wherein: be equipped with accredited testing organization (111) on parts platform (110), accredited testing organization (111) are including examining test table (6), electronic slide rail C (7), pressure sensor (8), the flexible end of electronic slide rail C (7) is provided with pressure sensor (8), the surface of examining test table (6) is seted up there is the dabber mouth.

10. The apparatus for testing the elasticity of the spindle spring according to claim 1, wherein: the support frame (104) is provided with three mandrel tables, and the mandrel tables are provided with mandrel grooves for placing mandrels (114).

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