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CN-224205366-U - Support structure of ion body power supply

CN224205366UCN 224205366 UCN224205366 UCN 224205366UCN-224205366-U

Abstract

The utility model discloses a supporting structure of an ion power supply, which comprises a power supply shell, a plurality of supporting units and a horizontal detecting unit, wherein the supporting units are distributed at the bottom of the power supply shell, the horizontal detecting unit comprises a detecting ball, a box body and a plurality of connecting rods, the detecting ball is arranged in the box body, the box body is arranged between the supporting units through the connecting rods, and when the detecting ball is deviated to contact with the outer wall of the box body, the ion power supply is disconnected. Through the sliding fit of supporting legs and supporting shoe and the synergism of tightening up the spring, the fine setting function of supporting unit cooperation regulating part is automatic to adapt to ground fluctuation, realizes quick horizontal calibration, is showing promotion equipment and is placing stability. The horizontal detection unit adopts a mechanical trigger structure, when the equipment is inclined to exceed a threshold value, the detection ball rolling contact electrode triggers power off, the response speed is high, the reliability is high, and the ion leakage or circuit fault is effectively prevented.

Inventors

  • WU LIJIANG
  • WU SHUQI

Assignees

  • 金华托菲电器有限公司

Dates

Publication Date
20260505
Application Date
20250516

Claims (9)

  1. 1. A support structure of an ion body power supply is characterized by comprising A power supply housing (1); a plurality of supporting units distributed at the bottom of the power supply shell (1), and The level detection unit comprises a detection ball (12), a box body (15) and a plurality of connecting rods (16), wherein the detection ball (12) is arranged in the box body (15), the box body (15) is arranged between the support units through the connecting rods (16), and when the detection ball (12) is deviated to be contacted with the outer wall of the box body (15) so as to disconnect an ion power supply.
  2. 2. A support structure for an ion source according to claim 1, wherein the support unit comprises a support leg (2) and a support block (3) located inside the support leg (2), the support block (3) being slidably connected in the support leg (2).
  3. 3. The support structure of an ion body power supply according to claim 2, wherein the support block (3) is connected with the inside of the support leg (2) through a tightening spring (4), and when the tightening spring (4) is in a static state, the support block (3) is accommodated in the support leg (2).
  4. 4. The support structure for an ion body power supply according to claim 3, wherein an adjusting member (5) is disposed between the support leg (2) and the support block (3), a through hole (6) is disposed on the support leg (2), and the through hole (6) is used for placing the adjusting member (5).
  5. 5. A support structure for an ion source according to claim 4, wherein the adjusting member (5) comprises a connecting post (7) and a conical block (8) at its end, the conical block (8) being placed between the support foot (2) and the support block (3).
  6. 6. The support structure of an ion body power supply according to claim 5, wherein a fixing block (10) is arranged between the support leg (2) and the support block (3), and a connecting hole (9) matched with the connecting column (7) is arranged in the fixing block (10).
  7. 7. A support structure for an ion source according to claim 1 or 6, wherein the housing (15) comprises a recess (11) for receiving a detection ball (12), the recess (11) being located in the centre of the housing (15).
  8. 8. The support structure of an ion power supply according to claim 7, wherein a first electrode (13) is arranged at the bottom of a box body (15) at one side of the groove (11), a second electrode (14) is arranged at the side surface of the box body (15), and when the detection ball (12) is simultaneously contacted with the first electrode (13) and the second electrode (14), the power supply body is powered off.
  9. 9. A support structure for an ion source according to claim 6, wherein the connecting post (7) is screwed to the fixed block (10).

Description

Support structure of ion body power supply Technical Field The utility model relates to the technical field of power supplies, in particular to a support structure of an ion power supply. Background In practical application scenarios of ion source, the devices often need to be placed on floors or operation tables with different flatness. Traditional bearing structure adopts fixed stabilizer blade more, is difficult to adapt to complicated ground condition, easily leads to equipment slope, influences power stability. In addition, the levelness requirement of the ion body power supply on the working state is high, and if the equipment is inclined due to external force or uneven ground, potential safety hazards such as internal ion body leakage and circuit short circuit can be possibly caused. Disclosure of utility model Aiming at the defects in the prior art, the utility model provides a support structure of an ion body power supply. The technical scheme is that the supporting structure of the ion body power supply comprises a power supply shell, a plurality of supporting units and a horizontal detecting unit, wherein the supporting units are distributed at the bottom of the power supply shell, the horizontal detecting unit comprises a detecting ball, a box body and a plurality of connecting rods, the detecting ball is arranged in the box body, the box body is arranged between the supporting units through the connecting rods, and when the detecting ball is deviated to contact with the outer wall of the box body, the ion body power supply is disconnected. In the above aspect, preferably, the supporting unit includes a supporting leg, and a supporting block located inside the supporting leg, and the supporting block is slidably connected in the supporting leg. In the above aspect, preferably, the supporting block is connected to the inside of the supporting leg through a tightening spring, and when the tightening spring is in a static state, the supporting block is accommodated in the supporting leg. In the above scheme, preferably, an adjusting piece is arranged between the supporting leg and the supporting block, a through hole is arranged on the supporting leg, and the through hole is used for placing the adjusting piece. In the above aspect, preferably, the adjusting member includes a connecting column and a conical block at an end thereof, and the conical block is placed between the supporting leg and the supporting block. In the above scheme, preferably, a fixing block is arranged between the supporting leg and the supporting block, and a connecting hole matched with the connecting column is arranged in the fixing block. In the above aspect, preferably, the case includes a groove for placing the detection ball, and the groove is located at the center of the case. In the above scheme, preferably, the bottom of the case body at one side of the groove is provided with a first electrode, the side surface of the case body is provided with a second electrode, and when the detection ball contacts with the first electrode and the second electrode at the same time, the power supply main body is powered off. In the above aspect, preferably, the connecting post is screwed to the fixing block. The support unit is matched with the fine adjustment function of the adjusting piece to automatically adapt to ground fluctuation through the sliding fit of the support legs and the support blocks and the synergistic effect of the tightening springs, so that quick horizontal calibration is realized, and the placement stability of equipment is remarkably improved. The horizontal detection unit adopts a mechanical trigger structure, when the equipment is inclined to exceed a threshold value, the detection ball rolling contact electrode triggers power off, the response speed is high, the reliability is high, and the ion leakage or circuit fault is effectively prevented. Drawings FIG. 1 is a schematic view of the whole of the present utility model. Fig. 2 is a schematic view of the entire bottom of the present utility model. Fig. 3 is a side view of the present utility model. Fig. 4 is a schematic view in the A-A direction of fig. 3. Fig. 5 is a schematic view of the B-B direction of fig. 3. Fig. 6 is an enlarged view at C of fig. 4. Fig. 7 is an enlarged view at D of fig. 5. Detailed Description The utility model is described in further detail below with reference to figures 1-7, which illustrate a support structure for an ion source, comprising a source housing 1, a plurality of support units distributed at the bottom of the housing, and a level detection unit. Specifically, the supporting unit is provided with four groups, wherein, the supporting unit includes supporting legs 2 to and wherein supporting shoe 3, supporting shoe 3 sliding connection is in the inside of supporting legs 2, just supporting shoe 3 is connected with supporting legs 2 inner wall through tightening spring 4, under the normality, tightening spring 4 accom