KR101734035B1 - clamp meter - Google Patents

Abstract

Disclosed is a clamp meter, comprising a housing and a clamp assembly coupled to an upper portion of the housing. The clamp meter comprises: first and second jaws connected by a pivot axis and pivotally moving from a closed position to an opened position; first and second magnetic sensors embedded in the first and second jaws, and measuring electrical characteristics from a wire passing through the inside when being in contact with each other at the closed position; a locking unit provided to regulate a pivotal movement of the first jaw in the closed position; and a trigger provided in a lower portion of the first jaw to release the lock by the lock unit by a primary operation and pivotally moving the first jaw from the closed position to the opened position by a secondary operation. The lock unit includes a stopper being in contact with a body of the trigger to prevent movement of the first jaw due to the compression of the body of the trigger in the closed position; a stopper guide for guiding a vertical movement of the stopper; and a compression spring for elastically supporting the stopper. A lock releasing trigger is primarily and solely compressed by a compression operation of the trigger to descend the stopper so as to release the lock of the lock unit. The body of the trigger is compressed with the lock releasing trigger together, after the lock of the lock unit is released, to pivotally move the first jaw.

Description

Clamp Meter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clamp meter capable of detecting a circuit current without cutting a circuit, and more particularly, to a clamp meter capable of minimizing a current measurement error.

 A clamp meter is known as a current meter with a built-in current transformer capable of measuring the circuit current without cutting the circuit. The clamp, the meter, has a conductive wire coil or metal loop that can be placed around the current-carrying wire. This conductive wire coil or metal loop measures the circuit current by sensing the induced field around the wire. A closed loop is required to provide a closed electrical path for current measurement, for which the clamp meter includes a clamp that can be opened and closed to fit around the wire. In measuring the electric current of the wire using the clamp meter, the clamp is opened in the current measurement state to cause a current measurement error although the clamp should not be opened in the current measurement state. The inventor of the present invention has also found that there is a geographical system as another cause for lowering the measurement accuracy of the clamp meter. The Earth is magnetic and has an enormous magnet structure of N and S poles in the Antarctic and the Arctic, and has a magnetic field that drives the compass in its entirety. When measuring the electric current of a wire using a conventional clamp meter, there is a difference between the current value measured according to the position or direction of the clamp meter. This difference arises from the above-mentioned ground system.

US Patent 6,456,060

SUMMARY OF THE INVENTION It is an object of the present invention to provide a clamping device capable of opening a clamp that is closed in a locked state through a primary trigger operation for releasing the locked state of the clamp closure and a secondary trigger operation for opening the clamp, A clamp meter capable of measuring current more reliably by preventing unclamping of the clamp.

A problem to be solved by the present invention is to open a clamp which is closed in a locked state through a primary trigger operation for releasing the locked state of the clamp closure and a secondary trigger operation for opening the clamp, Thereby reducing the current measurement error caused by the current measurement error.

According to an aspect of the present invention there is provided a clamp meter comprising a housing and a clamp assembly coupled to the top of the housing, the clamp meter comprising a first jaw connected to the pivot axis and pivotable from a closed position to an open position, And a second jaw; A first magnetic sensor and a second magnetic sensor embedded in the first jaw and the second jaw, the first magnetic sensor and the second magnetic sensor measuring electric characteristics from a wire passing through the inside when the first and second jaws come into contact with each other in the closed position; A locking unit provided to regulate the pivotal motion of the first jaws in the closed position; And a trigger provided at a lower portion of said first jaw and releasing the lock by said lock unit by a primary action and pivoting said first jaw from said closed position to said open position by a secondary action, The unit includes a stopper in contact with the trigger body to prevent movement of the first jaw due to the depression of the trigger body at the closed position, a stopper guide for guiding the upward and downward movement of the stopper, Wherein the lock unit is unlocked by unlocking the lock unit by unlocking the lock unit by depressing the stopper by a single pressing operation of the trigger by the pushing operation of the trigger, And is pushed together with an unlocking trigger to pivot the first jaw.

According to one embodiment, the trigger main body is subjected to an elastic force in a direction opposite to a pressing direction for opening the clamp by a tension spring provided between the first jaw and the second jaw, And a lock releasing portion pivotally connected to the pivot shaft together with the main body, the lock portion being pressed by an operator and extending downwardly from a lower side of the pressing portion, wherein an operator rotates about the pivot axis by pressing the pressing portion So that the end portion of the unlocking portion acts on the stopper to release the lock by the stopper.

According to one embodiment, the stopper includes a stop piece directly contacting with the trigger body and a cam sloped surface pressed against the unlocking trigger, wherein the stop piece protrudes upwardly from an area of the cam sloped surface, The unlocking trigger has a stopping hole for allowing passage of the stop piece when moving on the cam inclined surface while pushing the cam inclined surface.

According to one embodiment, the first jaw and the second jaw are formed by a pair of corresponding surfaces that meet or are spaced apart from each other by rotation of the first jaw about the pivot axis, A pair of semicylindrical recesses forming a single closed circular hole when the corresponding surface meets and a sharp tip formed to be acute with respect to the pair of corresponding surfaces.

According to one embodiment, the first magnetic sensor and the second magnetic sensor are disposed on a semicircular core that detects a magnetic field generated by a current flowing in a wire located inside the circular hole when the first magnetic sensor and the second magnetic sensor are in contact with each other, And a geomagnetic shield member made of a silicon steel plate for protecting the core from the geomagnetism, wherein the geomagnet shield member includes a circumferential shield portion covering the side surface, the inner circumferential curve surface and the outer circumferential surface of the core, As shown in Fig.

The clamp meter according to the present invention is configured to open a clamp that is closed in a locked state through a primary trigger operation for releasing the locked state of the clamp closure and a secondary trigger operation for opening the clamp, It is possible to more reliably measure the current by blocking the opening. Further, the clamp meter according to the present invention has an effect of reducing the current measurement error due to the geomagnetism. In addition, the clamp meter according to the present invention has a pointed tip of the first jaw and the second jaw and is made of a complex part, so that it is easy to access the narrow space of the apparatus.

1 is a perspective view illustrating a clamp meter according to an embodiment of the present invention.
2 is a perspective view showing the clamp assembly of the clamp meter shown in Fig.
FIG. 3 is a perspective view of a clamp assembly shown by removing a portion of the casing of the first and second jaws from the clamp assembly shown in FIG. 2. FIG.
Figure 4 is a cross-sectional view of the clamp assembly shown in Figures 2-3.
FIG. 5 is a detailed view illustrating a double trigger operation structure of a clamp meter according to an embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a clamp meter according to an embodiment of the present invention, FIG. 2 is a perspective view showing a clamp assembly of the clamp meter shown in FIG. 1, and FIG. 3 is a perspective view of the clamp assembly shown in FIG. FIG. 4 is a cross-sectional view of the clamp assembly shown in FIGS. 2 to 3, and FIG. 5 is a perspective view of a clamp meter according to an embodiment of the present invention. FIG. 5 is a detailed view showing a trigger double operation structure.

As shown in Figs. 1 to 5, the clamp meter 1 according to the embodiment of the present invention can measure electric characteristics such as electric current, voltage, electric resistance, etc. of an electric current flowing through the electric circuit without cutting the electric circuit And includes a housing 2000 and a clamp assembly 1000 coupled to the upper portion of the housing 2000 and the like.

The housing 2000 is provided in the palm of a hand so that it can be held by hand, and is formed of a lightweight rigid plastic material. A power supply unit including a battery is built in the housing 2000. Further, on the outer surface of the housing 2000, a plurality of push buttons 2100 for selecting various measurement functions of the clamp assembly 1000 and a plurality of push buttons 2100 for indicating the current, voltage and the like measured by the clamp assembly 1000 A display portion 2200 may be provided.

The clamp assembly 1000 includes a pair of jaws 1200, 1400, i.e., a first jaw 1200 and a second jaw 1400. The first jaw 1200 has its lower portion connected to the second jaw 1400 by the pivot shaft 1300 and pivots about the second jaw 1400. The first jaws 1200 and the second jaws 1400 may have a pair of corresponding surfaces 1201 and 1401 that meet or are spaced apart from each other by rotation about the pivot axis 1300, And a pair of semicircular recesses 1202 and 1402 formed on corresponding surfaces 1201 and 1401, respectively. When the first jaw 1200 and the second jaw 1400 are pivoted to meet the pair of corresponding surfaces 1201 and 1401, the semicircular recesses 1202 and 1402 are aligned to form one closed circular Thereby forming a hole. A position where the pair of semicircular recesses 1202 and 1402 are joined to form a closed circular hole is defined as a closed position and a position where the pair of semicircular recesses 1202 and 1402 are distant from each other is referred to as an open position define.

The first jaw 1200 is integrated with the trigger 1100 in the lower part and is movable between the closed position and the open position by the operation of the trigger 1100. The trigger 1100 includes a trigger main body 1120 integrally formed at a lower portion of the first jaw 1200 with the pivot shaft 1300 as a center, And an unlocking trigger 1140.

The lock unit 1900 is configured to lock the closed state by regulating the movement of the trigger body 1120 due to the depression thereof, and will be described in more detail below.

When the trigger 1100 is pushed toward the housing 2000 after the lock unit 1900 is unlocked, the first jaw 1200 integrated with the trigger main body 1120 rotates the pivot shaft 1300 And is moved away from the stationary second jaw 1400 to be in the open position. In the open position, a pair of semicircular recesses 1201 and 1401 are opened with respect to each other, so that the holes that were closed when these recesses 1201 and 1401 are fitted open. When the first jaw 1200 is in the open position a wire or the like can be positioned within the recess 1202 of the first jaw 1200 and the recess 1402 of the second jaw 1400, When the pushing operation of the trigger 1100 is released in a state where the trigger 1100 is positioned inside the recess 1202 of the first jaw 1200 and the recess 1402 of the second jaw 1400, The recess 1202 of the first jaw 1200 and the recess 1402 of the second jaw 1400 are aligned with each other by the resilient restoring force of the tension spring 1610, A closed circular hole is formed.

The first jaws 1200 and the second jaws 1400 include sharp tip ends 1203 and 1403 formed to have an acute angle with respect to the corresponding surfaces 1201 and 1401, 1203 and 1403 facilitate easy access of the clamp assembly 1000 to the narrow space by the complicated parts.

The trigger main body 1120 is elastically biased toward the closed position by the tension spring 1610 so that the trigger main body 1120 is always in the closed position until the trigger main body 1120 is pressed.

The first jaw 1200 and the second jaw 1400 are formed in a case structure to accommodate the internal elements. The first jaw 1200 has a semi-circular first magnetic sensor 1700 and the second jaw 1400 has a semi-circular second magnetic sensor 1800. The first magnetic sensor 1700 and the second magnetic sensor 1800 surround the periphery of the electric wire when the first jaw 1200 and the second jaw 1400 meet each other at their opposite ends Forms a closed circle, and senses the magnetic field generated by the current flowing through the wire at this time. The first magnetic sensor 1700 and the second magnetic sensor 1800 may include a first core 1720 formed of a metal laminate structure and / or an electric coil, and a second core 1820 .

 As described above, each of the first core 1720 and the second core 1740 is formed in a semicircular shape and includes a pair of side surfaces, an inner peripheral surface and an outer peripheral surface, and a pair of end surfaces . Each of the first magnetic sensor 1700 and the second magnetic sensor 1800 includes geomagnetic shields 1740 and 1840 to cover the outer sides of the first and second cores 1720 and 1820, The magnetic autonomous bodies 1740 and 1840 are provided with side surfaces of the cores 1720 and 1820, a peripheral shielding portion formed to cover the inner and outer curved surfaces and the outer peripheral curved surfaces, and end portions formed at the opposite ends of the two cores, Shielding portion. The geomagnetic shields 1740 and 1840 shield the first and second cores 1720 and 1820 from an external magnetic field to minimize measurement error due to the ground magnetic field. The first and second geomagnetic shields 1740 and 1840 are preferably made of silicon steel.

The lock unit 1900 includes a stopper 1910 which is in contact with the trigger main body 1120 to prevent the trigger main body 1120 from being pressed and thereby to release the clamp from the closed position, A stopper guide 1920 for guiding up and down movement, and a compression spring 1930 for elastically supporting the stopper 1910. The stopper guide 1920 includes an upper open shell structure in which the stopper 1910 is slidably received in a linear direction. The sliding protrusion formed on the lower portion of the stopper 1910 is fitted in the guide hole formed in the stopper guide 1920 so that the stopper 1910 can slide upward and downward. The compression spring 1930 elastically supports the stopper 1910 in the stopper guide 1920.

As described above, the trigger 1100 includes a trigger main body 1120 and an unlocking trigger 1120, and is capable of releasing the lock state of the lock unit 1900 by the single depression of the unlocking trigger 1140 Followed by a release of the clamp due to the unlocking trigger 1140 and trigger body 1120 being pressed together.

The trigger body 1120 is connected to the second jaw 1400 by a pivot shaft 1300 formed at a lower portion of the first jaw 1200 and is connected to the first jaw 1200 And a tension spring 1610 provided between the second jaw 1400 and the second jaw 1400. The second jaw 1400 receives the elastic force in a direction opposite to the pressing direction for opening the clamp. In addition, the unlock trigger 1140 may include: Includes a pushing portion pushed by the operator and pivotally connected to the pivot shaft 1300 together with the trigger main body 1120, and a lock releasing portion extending elongated from the lower side of the pushing portion. The unlocking trigger 1140 is rotated about the pivot shaft 1300 by an operator pressing the pushing portion so that the end portion of the unlocking portion acts on the stopper 1910 to lock the stopper 1910 It acts to release.

At this time, the unlocking trigger 1140 receives an elastic force in a direction opposite to the pressing direction by a spring 1630 interposed between the unlocking trigger 1140 and the trigger main body 1120.

The stopper 1910 includes a stop piece 1911 directly contacting with the trigger main body 1120 and a cam inclined surface 1912 pressed against the unlocking trigger 1140. The stop piece 1911 protrudes toward the upper side formed in one area of the cam inclined surface 1912. The unlocking trigger 1140 is provided with a stopper passage hole 1147 for allowing the passage of the stopper piece 1911 when moving on the cam inclined surface 1912 while pushing the cam surface 1912, .

In this structure, the unlocking trigger 1140 that rotates gradually pushes down the stopper 1910 by pushing the cam inclined surface 1146 gradually, so that the stop piece 1911 formed on the stopper 1910 is also lowered so that the trigger body 1120 In the lock state. The stopping hole 1147 allows the unlocking trigger 1140 to continuously rotate without being caught by the stopping piece 1911 to rotate integrally with the triggering main body 1120.

1: Clamp meter 1000: Clamp assembly
2000: housing 1200: first jaw
1300: Pivot axis 1400: second.
1700: first magnetic sensor 1800: second magnetic sensor
1100: Trigger 1120: Trigger body
1140: Unlock Trigger 1900: Locking Unit
1910: Stopper 1911: Stop

Claims (5)

CLAIMS A clamp meter comprising a housing and a clamp assembly coupled to the top of the housing,
A first jaw and a second jaw connected by a pivot shaft and pivotable from a closed position to an open position;
A first magnetic sensor and a second magnetic sensor embedded in the first jaw and the second jaw, the first magnetic sensor and the second magnetic sensor measuring electric characteristics from a wire passing through the inside when the first and second jaws come into contact with each other in the closed position;
A locking unit provided to regulate the pivotal motion of the first jaws in the closed position;
And a trigger provided at a lower portion of the first jaw to release the lock by the lock unit by a primary operation and to pivot the first jaw from the closed position to the open position by a secondary operation,
Wherein the lock unit includes a stopper in contact with the trigger body to prevent movement of the first jaw due to the depression of the trigger body at the closed position, a stopper guide to guide the vertical movement of the stopper, Wherein the lock release unit releases the lock unit by depressing the stopper only by a single pressing operation of the trigger to release the lock unit, And the second jaw is pushed together with the unlocking trigger to pivot the first jaw. The trigger mechanism according to claim 1, wherein the trigger main body is urged by a tension spring provided between the first jaw and the second jaw in a direction opposite to a pressing direction for opening the clamp, A pivot shaft pivotally connected to the pivot shaft, and a pressing part pressed by an operator and an unlocking part extended from a lower side of the pressing part, wherein the operator rotates about the pivot axis by pressing the pressing part And the end of the unlocking portion acts on the stopper to release the lock by the stopper. [3] The apparatus according to claim 2, wherein the stopper includes a stop piece directly contacting with the trigger body and a cam sloped surface pressed against the unlocking trigger, wherein the stop piece protrudes upward from an area of the cam sloped surface, Wherein the lock release trigger has a stopping hole for allowing the passage of the stop piece when moving on the cam inclined surface while pushing the cam inclined surface.  [2] The apparatus of claim 1, wherein the first jaw and the second jaw are formed on a pair of corresponding surfaces that meet each other or are distant from each other by rotation of the first jaw about the pivot axis, A pair of semicylindrical recesses forming one closed circular hole when said mating face meets and a sharp pointed portion formed to be acute with respect to said pair of mating faces. [2] The magnetic sensor of claim 1, wherein the first magnetic sensor and the second magnetic sensor comprise a semicircular core for detecting a magnetic field generated by a current flowing in a wire located inside the circular hole when the circular holes are in contact with each other, And a shielding member made of a silicon steel sheet for protecting the core from the earth magnetic system, wherein the geomagnetic shield comprises a peripheral shielding portion covering a side surface, an inner circumferential surface and an outer circumferential surface of the core, and an end portion And an end shielding portion formed at the end portion of the clamping portion.

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