阅读说明：本技术 一种高斯计探头导线的收卷结构 (Winding structure of gauss meter probe wire ) 是由 黄晓婷 于 2020-04-08 设计创作，主要内容包括：本发明公开了一种高斯计探头导线的收卷结构,包括高斯计、收卷支架,高斯计的右端面熔接有探头导线,探头导线的头部熔接有探头,收卷支架熔接在高斯计底部的右端,收卷支架的右端面开设有第一通孔、第二通孔,第二通孔位于第一通孔的正下方,收卷支架左端的上方转动设置有收卷转筒,收卷转筒的内部镶嵌有转轴,转轴的上下两端均贯穿出收卷转筒,转轴的上端向上嵌入高斯计的底部,转轴的下端向下贯穿过收卷支架,转轴的底部焊接有丝杠,丝杠的外表面螺纹连接有锁紧螺母,锁紧螺母的上表面均匀开设有防滑锯齿。通过收卷支架与收卷转筒的配合设置,收卷转筒能够起到捋线作用,防止探头导线产生缠绕、打结,便于探头导线存放。(The invention discloses a winding structure of a gauss meter probe wire, which comprises a gauss meter and a winding support, wherein the right end surface of the gauss meter is welded with a probe wire, the head of the probe wire is welded with a probe, the winding support is welded at the right end of the bottom of the gauss meter, the right end surface of the winding support is provided with a first through hole and a second through hole, the second through hole is positioned right below the first through hole, a winding rotary drum is rotatably arranged above the left end of the winding support, a rotary shaft is embedded in the winding rotary drum, the upper end and the lower end of the rotary shaft penetrate through the winding rotary drum, the upper end of the rotary shaft is upwards embedded into the bottom of the gauss meter, the lower end of the rotary shaft downwards penetrates through the winding support, a lead screw is welded at the bottom of the rotary shaft, the outer surface of the lead screw is in threaded connection with a locking nut, and the upper surface of the locking nut is uniformly provided with sawtooth anti-skid teeth. Through the cooperation setting of rolling support and rolling rotary drum, the rolling rotary drum can play the effect of stroking out with fingers the line, prevents that the probe wire from producing the winding, knoing, and the probe wire of being convenient for is deposited.)

1. The utility model provides a rolling structure of gauss meter probe wire, includes gauss meter (1), rolling support (4), its characterized in that:

a probe wire (2) is welded on the right end face of the gaussmeter (1), and a probe (3) is welded on the head of the probe wire (2);

the winding support (4) is welded at the right end of the bottom of the gaussmeter (1), a first through hole (401) and a second through hole (402) are formed in the right end face of the winding support (4), the second through hole (402) is located under the first through hole (401), a winding rotary drum (5) is rotatably arranged above the left end of the winding support (4), a rotary shaft (6) is embedded in the winding rotary drum (5), the upper end and the lower end of the rotary shaft (6) penetrate through the winding rotary drum (5), the upper end of the rotary shaft (6) is upwards embedded into the bottom of the gaussmeter (1), the lower end of the rotary shaft (6) penetrates through the winding support (4) downwards, a lead screw (8) is welded at the bottom of the rotary shaft (6), a locking nut (9) is connected to the outer surface of the lead screw (8) in a threaded manner, and anti-skid sawteeth (10) are uniformly formed on the upper surface of the locking nut (9), a cavity (601) is formed in the rotating shaft (6), and a return spring (7) is fixedly connected to the bottom surface of the interior of the cavity (601).

2. The winding structure of the wire of the gauss meter probe according to claim 1, wherein: the tail end of the probe lead (2) penetrates through the first through hole (401) and is connected with the gaussmeter (1), the middle end of the probe lead (2) is wound on the outer circumferential surface of the winding rotary drum (5), and the front end of the probe lead (2) penetrates through the second through hole (402) and is connected with the probe (3).

3. The winding structure of the wire of the gauss meter probe according to claim 2, wherein: the probe (3) is positioned right to the second through hole (402).

4. The winding structure of the wire of the gauss meter probe according to claim 1, wherein: the rotating shaft (6) is rotatably connected with the gaussmeter (1) and the winding support (4).

5. The winding structure of the wire of the gauss meter probe according to claim 1, wherein: the top of the cavity (601) is of an open structure.

6. The winding structure of the wire of the gauss meter probe according to claim 1, wherein: the top of the return spring (7) penetrates through the cavity (601) upwards and is fixedly connected with the bottom of the gaussmeter (1).

7. The winding structure of the wire of the gauss meter probe according to claim 1, wherein: and the locking nut (9) is positioned at the bottom of the left end of the rolling support (4).

Technical Field

The invention relates to the technical field of gauss meters, in particular to a winding structure of a probe wire of a gauss meter.

Background

A gauss meter (teslameter) made according to Hall effect principle has wide application in measuring magnetic field, and the instrument is composed of Hall probe as sensor and whole instrument. The size, performance and packaging structure of the Hall element in the probe play a key role in the accuracy of magnetic field measurement. The Hall probe generates Hall voltage in a magnetic field due to Hall effect, and the magnetic induction intensity can be determined according to a Hall voltage formula and a known Hall coefficient after the Hall voltage is measured.

The probes of the gauss meter in the prior art are connected with the slender conducting wires, the conducting wires are easy to wind and knot when the gauss meter is used, normal use is affected, and the slender conducting wires are not easy to wind and store when the gauss meter is stored.

Disclosure of Invention

The invention provides a winding structure of a wire of a gauss meter probe, which aims to solve the problems that the wire is easy to wind and knot when the gauss meter provided by the background technology is used, the normal use is influenced, and the slender wire is difficult to wind and store.

In order to achieve the purpose, the invention adopts the following technical scheme:

a winding structure of a gauss meter probe wire comprises a gauss meter and a winding support, wherein a probe wire is welded on the right end face of the gauss meter, a probe is welded on the head of the probe wire, the winding support is welded on the right end of the bottom of the gauss meter, a first through hole and a second through hole are formed in the right end face of the winding support, the second through hole is positioned under the first through hole, a winding rotary drum is rotatably arranged above the left end of the winding support, a rotary shaft is embedded in the winding rotary drum, the upper end and the lower end of the rotary shaft penetrate through the winding rotary drum, the upper end of the rotary shaft is upwards embedded into the bottom of the gauss meter, the lower end of the rotary shaft downwards penetrates through the winding support, a lead screw is welded at the bottom of the rotary shaft, a locking nut is connected to the outer surface of the lead screw in a threaded manner, anti-skid sawteeth are uniformly formed on the upper surface of the locking nut, a cavity is formed in the rotary shaft, and a return spring is fixedly connected to the bottom surface inside the cavity.

Furthermore, the tail end of the probe wire penetrates through the first through hole and is connected with the gaussmeter, the middle end of the probe wire is wound on the outer circumferential surface of the winding rotary drum, and the front end of the probe wire penetrates through the second through hole and is connected with the probe.

Further, the probe is positioned right to the second through hole.

Furthermore, the rotating shaft is rotatably connected with the gaussmeter and the winding support.

Further, the top of the cavity is of an open structure.

Furthermore, the top of the return spring penetrates out of the cavity upwards and is fixedly connected with the bottom of the gaussmeter.

Furthermore, the locking nut is located at the bottom of the left end of the winding support.

Compared with the prior art, the invention has the following beneficial effects:

through the cooperation setting of rolling support and rolling rotary drum, the rolling rotary drum can rotate on the rolling support, and the winding has the probe wire on the rolling rotary drum, so when the probe when using, the rolling rotary drum can play the line effect of smoothing out with fingers, prevents that the probe wire from producing the winding, knoing, when the probe does not use, the rolling rotary drum can autogyration with the elasticity rolling on the rolling rotary drum, the probe wire of being convenient for is deposited.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of the internal structure of the present invention.

FIG. 3 is an enlarged view of a portion of FIG. 2 according to the present invention.

Fig. 4 is an external structural view of the present invention.

In FIGS. 1-4: 1-gaussmeter, 2-probe wire, 3-probe, 4-rolling bracket, 401-first through hole, 402-second through hole, 5-rolling drum, 6-rotating shaft, 601-cavity, 7-reset spring, 8-lead screw, 9-locking nut and 10-anti-skid sawtooth.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will become apparent to those skilled in the art from the present disclosure.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings and described in the specification are only used for matching with the disclosure of the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions under which the present invention can be implemented, so that the present invention has no technical significance, and any structural modification, ratio relationship change, or size adjustment should still fall within the scope of the present invention without affecting the efficacy and the achievable purpose of the present invention. In addition, the terms "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for clarity of description, and are not intended to limit the scope of the present invention, and the relative relationship between the terms and the terms is not to be construed as a scope of the present invention.

Please refer to fig. 1 to 4:

the invention provides a winding structure of a gaussmeter probe wire, which comprises a gaussmeter 1 and a winding bracket 4, wherein each part of the winding structure of the gaussmeter probe wire is described in detail as follows:

the right end face of the gauss meter 1 is welded with a probe lead 2, the head of the probe lead 2 is welded with a probe 3, a rolling bracket 4 is welded at the right end of the bottom of the gauss meter 1, the right end face of the rolling bracket 4 is provided with a first through hole 401, the device comprises a first through hole 401, a second through hole 402, wherein the second through hole 402 is positioned right below the first through hole 401, a winding rotary drum 5 is rotatably arranged above the left end of a winding support 4, a rotary shaft 6 is embedded in the winding rotary drum 5, the upper end and the lower end of the rotary shaft 6 both penetrate through the winding rotary drum 5, the upper end of the rotary shaft 6 is upwards embedded into the bottom of a gaussmeter 1, the lower end of the rotary shaft 6 downwards penetrates through the winding support 4, a screw 8 is welded at the bottom of the rotary shaft 6, a locking nut 9 is in threaded connection with the outer surface of the screw 8, anti-skid sawteeth 10 are uniformly arranged on the upper surface of the locking nut 9, a cavity 601 is formed in the rotary shaft 6, and a reset spring 7 is fixedly connected to the bottom surface in the cavity 601;

specifically, the probe wire 2 is passed through the first through hole 401, wound around the take-up drum 5, and then passed out of the second through hole 402, therefore, when the probe 3 is pulled to the direction far away from the gauss meter 1, the probe wire 2 can drive the rolling rotary drum 5 to rotate, so that the probe wire 2 is lengthened, and the probe 3 is convenient to use, during the rotation of the winding drum 5, the return spring 7 inside the cavity 601 will also twist and generate elastic force, when the external force for pulling the probe 3 is removed, the return spring 7 drives the rotating shaft 6 and the winding rotary drum 5 to rotate by utilizing the elasticity, the extended probe lead 2 is wound on the winding rotary drum 5 again, and the winding rotary drum 5 has the function of wire smoothing through the structure, the probe lead 2 can be prevented from winding and knotting in use, and the probe lead 2 is convenient to store;

and at pivot 6 pivoted in-process, lead screw 8, lock nut 9 can follow synchronous rotation, nevertheless if manual twist lock nut 9 up moves, and make lock nut 9's anti-skidding sawtooth 10 closely laminate in the bottom of rolling support 4, at this moment lock nut 9 because and rolling support 4 between have great frictional force, so lock nut 9 just can't rotate, pivot 6 also can't rotate, then through this kind of structure, if need make rolling rotary drum 5 not rotate, only need to twist lock nut 9 can.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.