CN212474641U - Turnover frock is electroplated to probe - Google Patents

Abstract

A probe electroplating turnover tool is characterized in that a tool main body is a square frame body, wherein a square accommodating notch penetrating through the upper surface and the lower surface and a clamping groove located at the edge of the accommodating notch are formed in the middle position of the tool main body; the clamping grooves comprise a first clamping groove and a second clamping groove which are respectively positioned above one pair of opposite side edges of the accommodating notch, the length extending directions of the first clamping groove and the second clamping groove are perpendicular to the two side edges of the accommodating notch, the inner ends of the first clamping groove and the second clamping groove are communicated with the accommodating notch, and the first clamping groove and the second clamping groove are the same in quantity and opposite in position. The utility model discloses a probe electroplating turnover frock holds the probe through holding the breach, goes into PCB board both ends card through the draw-in groove, and its structural design can guarantee that under the prerequisite of mutual noninterference between the probe space utilization is high to turnover protective effect is good; in addition, the frock can pile up from top to bottom to improve the space utilization in the turnover transportation.

Description

Turnover frock is electroplated to probe

Technical Field

The utility model relates to a blood sugar test probe production frock field, more specifically the turnover frock is electroplated to probe that says so.

Background

The dynamic blood glucose monitoring system (RGMS) is a new type of continuous dynamic blood glucose monitoring system that has been put into clinical use in recent years and is connected to a probe, such as a needle, for placement in the subcutaneous tissue. The diameter of the probe is very small, and the patient does not feel pain or discomfort obviously when the probe is placed in the body. The instrument receives an electric signal reflecting blood sugar change from the probe at a certain time interval, and converts the average value of the electric signals collected for a plurality of times into the blood sugar value to be stored. Several hundred blood glucose values can be recorded per day. The dynamic blood glucose monitor can also simultaneously store the time of eating, moving, taking medicine and the like. Therefore, the patient can not suffer from acupuncture every day, and the blood glucose monitoring system can provide a daily blood glucose graph, a multi-day blood glucose graph fluctuation trend analysis and a summary of daily blood glucose data, and is a new breakthrough of blood glucose detection.

Wherein the production of probe is including electroplating, processes such as coating, need weld perpendicularly and switch on the PCB board when the probe is electroplated, and this kind of probe and PCB board vertically structure are difficult to be deposited and protect, so need use the frock to its firm the putting in turnover in-process to can not take place to interfere between the assurance probe and collide with, improve stability.

SUMMERY OF THE UTILITY MODEL

The utility model provides a probe electroplating turnover tool aiming at the defects of the prior art, which contains probes through containing gaps and clamps the two ends of a PCB board through clamping grooves, and has the advantages that the structural design can ensure that the space utilization rate is high and the turnover protection effect is good on the premise of no interference between the probes; in addition, the tools can be stacked up and down to improve the space utilization rate in the process of turnover transportation; the frock adopts the EVA material to have good buffering, antidetonation, thermal-insulated, dampproofing, chemical corrosion resistance, fungi-proofing waterproof advantage such as, and the safety and stability that can guarantee the probe is used as the turnover frock of probe.

The utility model has the following specific technical scheme that the probe electroplating turnover tool is characterized in that the tool main body is a square frame body, and a square accommodating notch penetrating through the upper surface and the lower surface and a clamping groove positioned at the edge of the accommodating notch are formed in the middle position of the tool main body; the clamping groove comprises a first clamping groove and a second clamping groove which are respectively positioned above a pair of sides opposite to the containing notch, the length extending direction of the first clamping groove and the second clamping groove is perpendicular to the two sides of the containing notch, the inner end of the first clamping groove and the inner end of the second clamping groove are communicated with the containing notch, and the first clamping groove and the second clamping groove are the same in quantity and opposite in position.

Therefore, the probes need to be vertically welded on the PCB for electrifying when being electroplated, and the structure that the probes are vertical to the PCB is difficult to store and protect, so that the probes need to be stably placed by using a tool in the turnover process; the accommodating notch is used for accommodating the probes, the clamping groove is used for clamping two ends of the PCB, the structural design of the PCB can ensure that the probes are high in space utilization rate on the premise of mutual noninterference, and the turnover protection effect is good.

As the utility model discloses a preferred, first draw-in groove with the second draw-in groove includes tank bottom, notch, the notch width is greater than the tank bottom width.

Therefore, the PCB is placed from the notch to the groove bottom more easily.

As the utility model discloses a preferred, notch one side is relative tank bottom homonymy side to the outside skew of the vertical projection of tank bottom.

Therefore, the PCB can be inclined after being clamped into the clamping grooves, and the interference between the clamped probes between the adjacent clamping grooves can be avoided.

As the utility model discloses a preferred, notch skew side with the tank bottom links up through ladder or inclined plane with between the same side.

Therefore, when a step or an inclined plane is formed between the side edge of the offset side of the notch and the side edge of the same side of the groove bottom, the PCB can be supported by the step angle or the inclined plane after being inclined, and the PCB is stably placed.

As the utility model discloses a preferred, it is in to hold the breach there is the extension district notch skew one side, the extension district both sides are not seted up the draw-in groove.

Therefore, the extending area is used for accommodating the longer end of the probe extending out relative to the PCB, so that the space utilization rate is improved.

As the utility model discloses a preferred, the draw-in groove is seted up in hold a pair of long limit of breach, draw-in groove evenly distributed, and quantity are no less than 5 groups.

Therefore, each probe electroplating turnover tool can store at least 5 groups of probes and PCB plates so as to ensure the space utilization rate.

As the optimization of the utility model, the upper surface of the tool is provided with a stacking groove which is concave downwards, and the accommodating notch and the clamping groove are both positioned at the inner groove bottom of the stacking groove; the lower surface of the tool is provided with stacking bulges which are convex downwards at the positions vertically opposite to the stacking grooves.

Therefore, the stacking bulge can be clamped into the stacking groove, so that the probe electroplating turnover tool can be vertically stacked, and the space utilization rate in the turnover transportation process is improved.

As a preferred aspect of the present invention, the stacking protrusion vertical height is smaller than the stacking groove vertical depth.

Therefore, the stacking bulge can be completely sunk into the stacking groove, so that the probe electroplating turnover tool is more stably stacked and placed.

As the utility model discloses an it is preferred, the material of turnover frock is electroplated to the probe is EVA.

Therefore, the EVA rubber-plastic product is a novel environment-friendly plastic foaming material, has the advantages of good buffering, shock resistance, heat insulation, moisture resistance, chemical corrosion resistance, bacteria resistance, water resistance and the like, and can ensure the safety and stability of the probe when used as a turnover tool of the probe.

To sum up, the utility model discloses following beneficial effect has:

the utility model discloses a probe electroplating turnover frock holds the probe through holding the breach, goes into PCB board both ends card through the draw-in groove, and its structural design can guarantee that under the prerequisite of mutual noninterference between the probe space utilization is high to turnover protective effect is good; in addition, the tools can be stacked up and down to improve the space utilization rate in the process of turnover transportation; the frock adopts the EVA material to have good buffering, antidetonation, thermal-insulated, dampproofing, chemical corrosion resistance, fungi-proofing waterproof advantage such as, and the safety and stability that can guarantee the probe is used as the turnover frock of probe.

Drawings

FIG. 1 is a perspective view of a probe electroplating turnaround tooling of the utility model 1;

FIG. 2 is a perspective view of the probe electroplating turnaround tooling of the utility model 2;

FIG. 3 is a cross-sectional view of a clamping groove of the probe electroplating turnover tool of the utility model;

FIG. 4 is a perspective view of the single probe electroplating turnover fixture of the present invention after the probe and the PCB are mounted thereon;

FIG. 5 is a perspective view showing a stacked state of the probe electroplating turnover tool of the present invention after the probe and the PCB are mounted thereon;

in the figure, 1-receiving notch, 11-extension, 2-card slot, 21-slot bottom, 22-slot opening, 2 a-first card slot, 2 b-second card slot, 3-stacking slot, and 4-stacking projection.

Detailed Description

The present invention will be further explained by the following embodiments with reference to the attached drawings.

Referring to fig. 1, 2, 3, 4 and 5, a probe electroplating turnover tool is a square frame, wherein a square accommodating notch 1 penetrating through the upper and lower surfaces and a clamping groove 2 located at the edge of the accommodating notch 1 are formed in the middle of the tool; the clamping groove 2 comprises a first clamping groove 2a and a second clamping groove 2b which are respectively positioned above a pair of side edges opposite to the containing notch 1, the length extending direction of the first clamping groove 2a and the second clamping groove 2b is perpendicular to the two side edges of the containing notch 1, the inner ends of the first clamping groove 2a and the second clamping groove 2b are communicated with the containing notch 1, and the first clamping groove 2a and the second clamping groove 2b are the same in quantity and opposite in position.

Therefore, the probes need to be vertically welded on the PCB for electrifying when being electroplated, and the structure that the probes are vertical to the PCB is difficult to store and protect, so that the probes need to be stably placed by using a tool in the turnover process; hold breach 1 and be used for holding the probe, draw-in groove 2 is used for going into PCB board both ends card, and its structural design can guarantee under the prerequisite of mutual noninterference under space utilization is high between the probe to the turnover protective effect is good.

As shown in fig. 1, 2, 3, 4, and 5, the first and second card slots 2a and 2b include a slot bottom 21 and a notch 22, and the width of the notch 22 is greater than the width of the slot bottom 21.

Therefore, the PCB is placed from the notch 22 to the groove bottom 21 more easily.

As shown in fig. 1, 2, 3, 4 and 5, one side edge of the notch 22 is offset from the same side edge of the groove bottom 21 to the outside of the vertical projection of the groove bottom 21.

Therefore, the PCB can be inclined after being clamped into the clamping grooves 2, and the interference between the clamped probes between the adjacent clamping grooves 2 can not be formed.

As shown in fig. 1, 2, 3, 4 and 5, the offset side of the slot 22 is engaged with the same side of the slot bottom 21 by a step or a slope.

Therefore, when a step or an inclined plane is formed between the offset side edge of the notch 22 and the same side edge of the groove bottom 21, the PCB can be supported by the step angle or the inclined plane after being inclined, so that the PCB is stably placed.

As shown in fig. 1, 4 and 5, the receiving notch 1 has an extension section 11 on the offset side of the notch 22, and the two sides of the extension section 11 are not provided with the card slots 2.

Thus, the extension 11 is used to accommodate the longer end of the probe that protrudes relative to the PCB, to improve space utilization.

As shown in fig. 1, fig. 2, fig. 4, and fig. 5, the card slots 2 are opened on a pair of long sides of the accommodating notch 1, and the card slots 2 are uniformly distributed and not less than 5 groups.

From this, every probe electroplating turnover frock can deposit 5 groups of probes and PCB board at least to guarantee space utilization.

As shown in fig. 1, 2, 4 and 5, a stacking groove 3 which is recessed downwards is formed in the upper surface of the tool, and the accommodating notch 1 and the clamping groove 2 are both located at the bottom of the stacking groove 3; the lower surface of the tool is provided with a stacking bulge 4 which is bulged downwards at a position vertically opposite to the stacking groove 3.

From this, pile up protruding 4 and can block into and pile up in the groove 3, make the probe electroplate turnover frock and can pile up from top to bottom to improve the space utilization in the turnover transportation.

As shown in fig. 1, 2, 4 and 5, the vertical height of the stacking projection 4 is smaller than the vertical depth of the stacking groove 3.

From this, it can sink into totally and pile up groove 3 to pile up protruding 4, makes the probe electroplate turnover frock and piles up to put more stably.

The material of turnover frock is electroplated to probe is EVA.

Therefore, the EVA rubber-plastic product is a novel environment-friendly plastic foaming material, has the advantages of good buffering, shock resistance, heat insulation, moisture resistance, chemical corrosion resistance, bacteria resistance, water resistance and the like, and can ensure the safety and stability of the probe when used as a turnover tool of the probe.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solution of the present invention by those skilled in the art should fall into the protection scope of the present invention, and the technical contents claimed by the present invention have been fully recorded in the claims.

Claims (9)

1. The utility model provides a turnover frock is electroplated to probe which characterized in that: the tool main body is a square frame body, and a square accommodating notch (1) penetrating through the upper surface and the lower surface and a clamping groove (2) positioned at the edge of the accommodating notch (1) are formed in the middle position of the tool main body; the clamping groove (2) comprises a first clamping groove (2 a) and a second clamping groove (2 b) which are respectively positioned above one pair of opposite side edges of the accommodating notch (1), the length extending direction of the first clamping groove (2 a) and the second clamping groove (2 b) is perpendicular to the two side edges of the accommodating notch (1), the inner ends of the first clamping groove and the second clamping groove are communicated with the accommodating notch (1), and the first clamping groove (2 a) and the second clamping groove (2 b) are identical in number and opposite in position.

2. The turnover frock of probe electroplating of claim 1, characterized in that: the first clamping groove (2 a) and the second clamping groove (2 b) comprise a groove bottom (21) and a notch (22), and the width of the notch (22) is larger than that of the groove bottom (21).

3. The turnover frock of probe electroplating of claim 2, characterized in that: the side edge of one side of the notch (22) is offset towards the outside of the vertical projection of the groove bottom (21) relative to the side edge of the same side of the groove bottom (21).

4. The turnover frock of probe electroplating of claim 3, characterized in that: the offset side edge of the notch (22) is connected with the same side edge of the groove bottom (21) through a step or an inclined surface.

5. The turnover frock of probe electroplating of claim 3, characterized in that: the accommodating notch (1) is provided with an extension area (11) on one offset side of the notch (22), and the clamping groove (2) is not formed in two sides of the extension area (11).

6. The turnover frock of probe electroplating of claim 1, characterized in that: draw-in groove (2) set up in hold a pair of long limit of breach (1), draw-in groove (2) evenly distributed, and quantity are no less than 5 groups.

7. The turnover frock of probe electroplating of claim 1, characterized in that: the upper surface of the tool is provided with a stacking groove (3) which is sunken downwards, and the accommodating notch (1) and the clamping groove (2) are both positioned at the bottom of the stacking groove (3); the lower surface of the tool is vertically opposite to the stacking groove (3) and provided with a stacking bulge (4) protruding downwards.

8. The turnover frock of probe electroplating of claim 7, characterized in that: the vertical height of the stacking projection (4) is smaller than the vertical depth of the stacking groove (3).

9. The probe electroplating turnover tool according to any one of claims 1 to 8, characterized in that: the probe electroplating turnover tool is made of EVA.

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