JP2017097979A - Electromagnetic contactor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electromagnetic contactor capable of suppressing the tilt of a shaft which connects a movable contact and a movable plunger, in relative to the movable plunger.SOLUTION: An electromagnetic contactor 1 comprises: a contact point mechanism 2 including a pair of stationary contacts 23 and 24 including stationary contact points 23d and 24d and a movable contact 25 of which movable contact points 25a and 25b in both ends can be brought into contact with and separated from the stationary contact points 23d and 24d of the pair of stationary contacts 23 and 24; and an electromagnet unit 3 which includes a movable plunger 35 coupled to the movable contact 25 by a shaft 36 and drives the contact mechanism 2. In the movable plunger 35, a through-hole 35c for shaft through which the shaft can be inserted is formed and in the through-hole 35c for shaft, a female screw 35e is formed. In the shaft 36, a male screw part 36d which is threaded with the female screw part 35e is formed. In the movable plunger 35 and the shaft 36, a guide mechanism 37 which makes an axial center of the shaft 36 and an axial center of the through-hole 35c for shaft coaxial is provided.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electromagnetic contactor that opens and closes a current path.

As an electromagnetic contactor that opens and closes a current path, for example, the one described in Patent Document 1 is known.
The electromagnetic contactor described in Patent Document 1 includes a contact mechanism having a pair of fixed contacts, a movable contact that can be moved to and away from the pair of fixed contacts by movable contacts at both ends, and an electromagnet unit that drives the contact mechanism. It has. The electromagnet unit has a fixed plunger (fixed iron core), a movable plunger (movable iron core) connected to the movable contact of the contact mechanism by a shaft, and generates an exciting force by the electromagnet unit by exciting the movable plunger (movable iron core). ) To drive the excitation winding.
Here, the shaft is formed of a non-magnetic material in the shape of a round bar that is long in the moving direction (vertical direction) of the movable plunger (movable iron core), and its upper end is prevented from being detached from the movable contact. Yes. Further, the shaft is inserted through a through hole formed so as to penetrate the fixed plunger (fixed iron core) in the vertical direction, and the lower end portion thereof is coupled to the movable plunger (movable iron core).

JP 2007-287572 A

However, the coupling of the movable plunger to the shaft has the following problems.
That is, when the shaft and the movable plunger are coupled, there is a problem that the shaft is inclined with respect to the movable plunger due to the clearance between the shaft and the movable plunger, and the movable plunger is joined to the shaft in this state. That is, the movable plunger is coupled to the shaft in a state where the shaft center is inclined with respect to the axis of the movable plunger.
When the movable plunger is coupled to the shaft with the shaft axis inclined with respect to the axis of the movable plunger, the movable contact connected to the upper end of the shaft is inclined with respect to the pair of fixed contacts. There is a shift in the timing at which the movable contacts at both ends of the contact come into contact with the pair of fixed contacts. When this timing shifts, the wiping amount of the movable contacts at both ends of the movable contact with respect to the fixed contacts (the amount that each movable contact pushes into the fixed contacts) varies between the movable contacts. As a result, the contact pressure of the movable contact with respect to the fixed contact varies between the movable contacts, which may adversely affect the formation of the current path.

  Accordingly, the present invention has been made to solve the above-described problems, and an object thereof is to provide an electromagnetic contactor capable of suppressing the inclination of the shaft connecting the movable contact and the movable plunger with respect to the movable plunger. There is to do.

  In order to achieve the above object, an electromagnetic contactor according to an aspect of the present invention includes a pair of fixed contacts each having a fixed contact and movable contacts at both ends of the pair of fixed contacts. A contact mechanism having a separable movable contact; and an electromagnet unit for driving the contact mechanism having a movable plunger connected to the movable contact by a shaft, and the shaft can be inserted into the movable plunger. A through hole for the shaft is formed and a female thread portion is formed in the through hole for the shaft, and a male thread portion that is screwed into the female thread portion is formed in the shaft, and the movable plunger and the shaft are connected to the shaft. The gist of the present invention is that a guide mechanism is provided in which the shaft center and the shaft center of the shaft through hole are coaxial.

  According to the electromagnetic contactor which concerns on this invention, the electromagnetic contactor which can suppress the inclination with respect to the movable plunger of the shaft which connects a movable contact and a movable plunger can be provided.

It is sectional drawing which shows the electromagnetic contactor which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the coupling | bonding state of the movable plunger and shaft of the electromagnetic contactor shown in FIG. FIG. 3 is a perspective view showing a movable plunger and a shaft shown in FIG. 2. It is sectional drawing which shows the coupling | bonding state of the movable plunger and shaft of an electromagnetic contactor which concern on 2nd Embodiment of this invention. It is a perspective view which shows the movable plunger and shaft which are shown in FIG. It is sectional drawing which shows the coupling | bonding state of the movable plunger and shaft of an electromagnetic contactor which concern on 3rd Embodiment of this invention. It is sectional drawing which shows the coupling | bonding state of the movable plunger and shaft of an electromagnetic contactor which concern on 4th Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
The electromagnetic contactor according to the first embodiment of the present invention is shown in FIG. 1, and the electromagnetic contactor 1 includes a contact mechanism 2 and an electromagnet unit 3 that drives the contact mechanism 2.
The contact mechanism 2 is housed in a contact mechanism housing case 4, and the contact mechanism housing case 4 is made of a metal rectangular tube 5 and a flat ceramic plate that closes the upper end of the rectangular tube 5. And an insulating substrate 6. The rectangular tube 5 has a flange portion 5 a that protrudes outward at the lower end portion, and the flange portion 5 a is sealed to the upper surface of the magnetic yoke 7. A pair of through holes 6a and 6b are formed in the insulating substrate 6 at a predetermined interval. Metallization processing is applied to the positions around the through-holes 6a and 6b on the upper surface of the insulating substrate 6 and the positions where the rectangular tube 5 contacts on the lower surface of the insulating substrate 6.

The contact mechanism 2 includes a pair of fixed contacts 23 and 24 (hereinafter referred to as a first conductor portion 21 and a second conductor portion 22) fixed to the insulating substrate 6 via a pair of conductor portions 21 and 22 (hereinafter referred to as a first conductor portion 21 and a second conductor portion 22). And the first fixed contact 23 and the second fixed contact 24), and the movable contact 25 arranged so as to be able to contact with and separate from the first fixed contact 23 and the second fixed contact 24. I have. The first conductor portion 21 is inserted and fixed in the through hole 6 a of the insulating substrate 6, and the second conductor portion 22 is inserted and fixed in the through hole 6 b of the insulating substrate 6.
Here, the first fixed contact 23 is a C-shaped conductive plate made of a conductive metal portion in a side view, and extends upward along the lower surface of the insulating substrate 6 and an upper plate portion 23a. An intermediate plate portion 23b extending downward from the outer end portion and a lower plate portion 23c extending inward from the lower end portion of the intermediate plate portion 23b in parallel with the upper plate portion 23a. The lower plate portion 23c includes a first fixed contact 23d that extends below the movable contact 25 and contacts a first movable contact 25a (described later) of the movable contact 25 on the upper surface thereof.

On the other hand, the second fixed contact 24 is also a C-shaped conductive plate in a side view made of a conductive metal part, like the first fixed contact 23, and extends outward along the lower surface of the insulating substrate 6. A plate portion 24a, an intermediate plate portion 24b extending downward from the outer end portion of the upper plate portion 24a, and a lower plate portion 24c extending inward from the lower end portion of the intermediate plate portion 24b in parallel with the upper plate portion 24a. ing. The lower plate portion 24c includes a second fixed contact 24d that extends below the movable contact 25 and contacts a second movable contact 25b described later of the movable contact 25 on the upper surface thereof.
Each of the first fixed contact 23 and the second fixed contact 24 fixes the first conductor by fixing the pins formed on the lower end surfaces thereof to the first conductor portion 21 and the second conductor portion 22, respectively. It is fixed to each of the part 21 and the second conductor part 22. Examples of a method for fixing the pin to the first conductor portion 21 and the second conductor portion 22 include brazing and screwing.

In addition, a U-shaped magnetic plate 28 as viewed from above is provided so as to cover the inner surface of the intermediate plate portion 23b of the first fixed contact 23 and the inner surface of the intermediate plate portion 24b of the second fixed contact 24. It is installed. Thereby, the magnetic field generated by the current flowing through the intermediate plate portions 23b and 24b can be shielded.
Furthermore, a synthetic resin insulating cover 26 that restricts the occurrence of arc is attached to the first fixed contact 23, and an insulating cover 27 made of synthetic resin that restricts the occurrence of arc is also attached to the second fixed contact 24. Is installed. As a result, only the first fixed contact 23 d on the upper surface side of the lower plate portion 23 c is exposed on the inner peripheral surface of the first fixed contact 23. Further, only the second fixed contact 24 d on the upper surface side of the lower plate portion 24 c is exposed on the inner peripheral surface of the second fixed contact 24.

  The movable contact 25 is a conductive plate that is long in the left-right direction in FIG. 1 and made of a conductive metal material, and both end portions are arranged in the first fixed contact 23 and the second fixed contact 24. It is arranged. A first movable contact 25 a that contacts the first fixed contact 23 d of the first fixed contact 23 is provided on the lower surface of one end (left end in FIG. 1) of the movable contact 25, and the lower surface of the other end of the movable contact 25. Is provided with a second movable contact 25 b that contacts the second fixed contact 24 d of the second fixed contact 24. The movable contact 25 is supported by a shaft 36 coupled to a later-described movable plunger 35 of the electromagnet unit 3. A through hole through which the shaft 36 is inserted is formed at the center of the movable contact 25.

  Further, the shaft 36 is formed in a round bar shape that is long in the moving direction (vertical direction) of the movable plunger 35, and a C-ring groove 36 a is formed in the vicinity of the upper end of the shaft 36. The flange portion 36b is formed to protrude outward. The movable contact 25 is placed on the flange portion 36 b through the through hole from above the shaft 36. Then, the contact spring 40 is inserted from above the shaft 36, the fixing member 39 is inserted from above the shaft 36 to the shaft 36, and the upper end of the contact spring 40 is fixed to the fixing member 39 so as to obtain a predetermined urging force by the contact spring 40. Stop by. The upward movement of the fixing member 39 is restricted by the C ring 41 fitted into the C ring groove 36 a of the shaft 36.

The movable contact 25 is in a released state, and the first movable contact 25a and the second movable contact 25b at both ends are the first fixed contact 23d of the first fixed contact 23 and the second fixed contact 24d of the second fixed contact 24, respectively. It will be in the state spaced apart from each of these at predetermined intervals. In addition, the movable contact 25 is in the closing position, and the first movable contact 25a and the second movable contact 25b at both ends are the second fixed contact 23d of the first fixed contact 23 and the second fixed contact 24 of the second fixed contact 24, respectively. Each contact point 24d is set to contact with a predetermined contact force by the contact spring 40.
Moreover, as shown in FIG. 1, the insulating cylinder part 12 formed in the shape of a bottomed square cylinder is arrange | positioned at the internal peripheral surface of the square cylinder 5 of the contact mechanism accommodation case 4. As shown in FIG. The insulating cylinder portion 12 has an insulating function to block the influence of the arc on the metal square cylinder 5.

Further, as shown in FIG. 1, the electromagnet unit 3 has a U-shaped lower magnetic yoke 31 as viewed from the side, and a fixed plunger 32 is disposed at the center of the bottom plate portion of the lower magnetic yoke 31. . A spool 33 is disposed outside the fixed plunger 32.
As shown in FIG. 1, the spool 33 includes a central cylindrical portion 33a through which the fixed plunger 32 is inserted, a lower flange portion 33b projecting radially outward from a lower end portion of the central cylindrical portion 33a, and an upper end portion of the central cylindrical portion 33a. And an upper flange portion 33c protruding outward in the radial direction. As shown in FIG. 1, an exciting coil 34 is wound around a storage space formed by the central cylindrical portion 33 a, the lower flange portion 33 b, and the upper flange portion 33 c of the spool 33.

A plate-like magnetic yoke 7 is fixed to the upper end that is the open end of the lower magnetic yoke 31. A movable plunger through hole 7 a is formed at the center of the magnetic yoke 7.
In addition, a cap 8 formed in a bottomed cylindrical shape is disposed on the upper portion of the fixed plunger 32 disposed in the central cylindrical portion 33 a of the spool 33, and radially outwardly provided at the open end of the cap 8. The protruding flange portion 8 a is sealed and joined to the lower surface of the magnetic yoke 7. Thus, a sealed container is formed in which the contact mechanism housing case 4 and the cap 8 are communicated with each other via the movable plunger through hole 7a of the magnetic yoke 7.

  A movable plunger 35 coupled to the lower side of the shaft 36 is accommodated inside the cap 8 so as to be movable in the vertical direction. The movable plunger 35 includes a cylindrical portion 35a that is accommodated in the cap 8 so as to be movable in the vertical direction, and a peripheral flange portion 35b that is provided at the upper end of the cylindrical portion 35a and projects outward in the radial direction. . The cylindrical portion 35a of the movable plunger 35 is vertically inserted through the movable plunger through hole 7a of the magnetic yoke 7, and the peripheral flange portion 35b of the movable plunger 35 has a larger outer diameter than the movable plunger through hole 7a. 7 is disposed above.

The cylindrical portion 35a of the movable plunger 35 is formed with a return spring accommodating recess 35d that extends upward from its lower end surface. A return spring 38 for biasing the movable plunger 35 upward is disposed between the bottom of the cap 8 and the upper end surface of the return spring accommodating recess 35d.
The coupling of the movable plunger 35 to the shaft 36 will be described in detail later.
Further, as shown in FIG. 1, the permanent magnet 9 formed in an annular shape with a square outer shape and a central opening on the upper surface of the magnetic yoke 7 surrounds the peripheral flange portion 35 b of the movable plunger 35. It is fixed. The permanent magnet 9 is magnetized in the vertical direction, that is, in the thickness direction so that the upper end side is, for example, an N pole and the lower end side is an S pole.
Further, on the upper surface of the permanent magnet 9, an auxiliary yoke 10 having the same outer shape as the permanent magnet 9 and having a smaller inner diameter than the peripheral flange portion 35 b of the movable plunger 35 is fixed. The shaft 36 is inserted through the through hole of the auxiliary yoke 10 in the vertical direction.

Further, an elastic plate-like foreign matter intrusion preventing member 11 is fixed to the upper surface of the auxiliary yoke 10. The foreign matter intrusion prevention member 11 has an outer shape that is substantially the same size as the auxiliary yoke 10, and has a through hole having an inner diameter that passes through the shaft 36 in the vertical direction and contacts the outer peripheral surface of the shaft 36. The foreign matter intrusion prevention member 11 is made of rubber, for example. This foreign matter intrusion prevention member 11 is used when a foreign matter such as a melt or a flaw generated near the first fixed contact 23d of the first fixed contact 23 or the second fixed contact 24d of the second fixed contact 24 falls downward. In addition, it has a function of preventing the foreign matter from entering the movable plunger 35 side. The foreign matter intrusion preventing member 11 has elasticity and has a function of urging the insulating cylinder portion 12 on the upper side of the foreign matter intrusion preventing member 11 upward.
Then, a plate-like magnetic yoke 7 having a movable plunger through-hole 7a that passes through the movable plunger 35 in the vertical direction, a contact mechanism housing case 4 that is joined to the upper surface of the magnetic yoke 7 and houses the contact mechanism 2 therein, A sealed housing chamber for housing the contact mechanism 2, the shaft 36 and the movable plunger 35 is constituted by the cap 8 which is joined to the lower surface of the magnetic yoke 7 and houses the movable plunger 35 therein, and this sealed housing chamber. Is filled with arc extinguishing gas.

Next, the coupling of the movable plunger 35 to the shaft 36 will be described in detail.
At the center of the movable plunger 35, as shown in FIG. 2, a shaft through hole 35c through which a shaft 36 formed in a round bar shape can be inserted extends from the upper surface 35ba of the peripheral flange portion 35b to the upper end surface of the return spring accommodating recess 35d. It is formed to penetrate. The shaft through hole 35c is a round hole. An internal thread portion 35e is formed at a substantially central portion in the vertical direction of the shaft through hole 35c. A movable plunger side first guide portion 35f having an inner diameter slightly larger than the inner diameter of the female screw portion 35e is formed above the female screw portion 35e of the shaft through hole 35c. Furthermore, a movable plunger side second guide portion 35g having an inner diameter slightly smaller than the inner diameter of the female screw portion 35e is formed below the female screw portion 35e of the shaft through hole 35c.

  On the other hand, on the lower side of the flange portion 36b of the shaft 36, as shown in FIGS. 2 and 3, a male screw portion 36d that engages with the female screw portion 35e on the movable plunger 35 side is formed. A shaft-side first guide portion 36c that is an intermediate fit with respect to the movable plunger-side first guide portion 35f is formed above the male screw portion 36d of the shaft 36 and below the flange portion 36b. Yes. Further, a shaft-side second guide portion 36e serving as an intermediate fit with respect to the movable plunger-side second guide portion 35g is formed below the male screw portion 36d of the shaft 36. The fitting tolerance between the movable plunger side first guide part 35f and the shaft side first guide part 36c is about h on the basis of the axis. The fitting tolerance between the movable plunger side second guide part 35g and the shaft side second guide part 36e is about h on the basis of the axis. The fit tolerance can be arbitrarily designed as long as it can suppress the inclination of the shaft 36 with respect to the movable plunger 35 and can be easily assembled. For example, a clearance fit of about g on the axis basis may be used, and an intermediate fit of about k or m on the axis basis may be used.

When the movable plunger 35 is coupled to the shaft 36, the female screw portion 35 e of the movable plunger 35 is screwed into the male screw portion 36 d of the shaft 36 from the lower side of the shaft 36. The screwing amount of the female screw portion 35e of the movable plunger 35 with respect to the male screw portion 36d of the shaft 36 is determined according to the predetermined vertical position of the movable plunger 35.
When the female thread portion 35e of the movable plunger 35 is screwed into the male thread portion 36d of the shaft 36, the movable plunger side first guide portion 35f and the shaft side first guide portion 36c become an intermediate fit, and the movable plunger side second guide. The portion 35g and the shaft-side second guide portion 36e are an intermediate fit. Thereby, the axial center of the shaft 36 and the axial center of the through-hole 35c for shafts become coaxial. Accordingly, the movable plunger side first guide portion 35f and the movable plunger side second guide portion 35g formed on both sides of the female screw portion 35e of the shaft through hole 35c, and the both sides of the male screw portion 36d of the shaft 36, the movable plunger The shaft center of the shaft 36 and the shaft penetration are formed by the shaft-side first guide portion 36c and the shaft-side second guide portion 36e that are intermediate fits to the side first guide portion 35f and the movable plunger-side second guide portion 35g. A guide mechanism 37 is formed so that the axis of the hole 35c is coaxial.

Then, after the female screw portion 35e of the movable plunger 35 is screwed into the male screw portion 36d of the shaft 36, the lower end portion of the shaft 36 and the upper end surface of the return spring accommodating recess 35d of the movable plunger 35 are joined by welding.
Thereby, the movable plunger 35 is coupled to the shaft 36.
Here, since the shaft center of the shaft 36 and the shaft center of the shaft through-hole 35c are made coaxial by the guide mechanism 37, when the movable plunger 35 is coupled to the shaft 36, the inclination of the shaft 36 with respect to the movable plunger 35 is increased. Can be suppressed. Therefore, the first movable contact 25a and the second movable contact 25b are set to the wipe amount of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d. It is possible to suppress variations occurring between the two.

  The guide mechanism 37 is provided on both sides of the movable plunger side first guide part 35f and the movable plunger side second guide part 35g formed on both sides of the female thread part 35e of the shaft through hole 35c, and the male thread part 36d of the shaft 36. Since it is formed by the shaft-side first guide portion 36c and the shaft-side second guide portion 36e that are formed and are intermediate fits with respect to the movable plunger-side first guide portion 35f and the movable plunger-side second guide portion 35g, The coaxial function of the movable plunger 35 and the shaft 36 is exhibited on both sides of the threaded portion of the shaft 36 and the movable plunger 35, and the movable plunger 35 and the shaft 36 are engaged on one side of the threaded portion of the shaft 36 and the movable plunger 35. The coaxial function can be enhanced as compared with the case where the coaxial function is exhibited.

Next, operation | movement of the electromagnetic contactor 1 of 1st Embodiment is demonstrated.
Now, the first conductor portion 21 connected to the first fixed contact 23 is connected to, for example, a power supply source that supplies a large current, and the second conductor portion 22 connected to the second fixed contact 24 is connected to the load device. It shall be connected.
In this state, it is assumed that the exciting coil 34 in the electromagnet unit 3 is in a non-excited state and the electromagnet unit 3 is in a released state in which no exciting force for lowering the movable plunger 35 is generated.

In this released state, the movable plunger 35 is urged upward by the return spring 38 away from the magnetic yoke 7. At the same time, the attractive force generated by the magnetic force of the permanent magnet 9 acts on the auxiliary yoke 10 and the peripheral flange portion 35b of the movable plunger 35 is attracted. For this reason, the upper surface of the peripheral flange portion 35 b of the movable plunger 35 is in contact with the lower surface of the auxiliary yoke 10.
Therefore, the first movable contact 25 a and the second movable contact 25 b of the movable contact 25 of the contact mechanism 2 connected to the movable plunger 35 via the shaft 36 are the first fixed contact 23 d of the first fixed contact 23. The second fixed contact 24 is spaced apart from the second fixed contact 24d by a predetermined distance upward. For this reason, the current path between the first stationary contact 23 and the second stationary contact 24 is in a cut-off state, and the contact mechanism 2 is in an open state.

When the exciting coil 34 of the electromagnet unit 3 is energized from this released state, an exciting force is generated in the electromagnet unit 3, and the movable plunger 35 is urged by the return spring 38 and the attracting force of the permanent magnet 9 through the fixed plunger 32. Push down against. The lowering of the movable plunger 35 stops when the lower surface of the peripheral flange portion 35 b hits the upper surface of the magnetic yoke 7.
In this manner, when the movable plunger 35 is lowered, the movable contact 25 connected to the movable plunger 35 via the shaft 36 is also lowered, and the first movable contact 25a and the first movable contact 25a of the movable contact 25 of the contact mechanism 2 are lowered. Each of the two movable contacts 25b comes into contact with each of the first fixed contact 23d of the first fixed contact 23 and the second fixed contact 24d of the second fixed contact 24 with the contact pressure of the contact spring 40.
For this reason, the large current of the power supply source is in a closed state in which it is supplied to the load device through the first fixed contact 23, the movable contact 25 and the second fixed contact 24.

  Here, the first movable contact 25a and the second movable contact 25b of the movable contact 25 are respectively the first fixed contact 23d of the first fixed contact 23 and the second fixed contact 24d of the second fixed contact 24. The inclination of the shaft 36 with respect to the movable plunger 35 is suppressed when contacting with respect to. Therefore, the first movable contact 25a and the second movable contact 25b are set to the wipe amount of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d. It is possible to suppress variations occurring between the two. Thereby, the contact pressure of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d is changed between the first movable contact 25a and the second movable contact 25b. And the current path is smoothly formed.

Then, when the current supply to the load device is interrupted from the closed state of the contact mechanism 2, the energization to the excitation coil 34 of the electromagnet unit 3 is stopped.
When the energization to the exciting coil 34 is stopped, the exciting force that moves the movable plunger 35 downward by the electromagnet unit 3 disappears, so that the movable plunger 35 is raised by the urging force of the return spring 38, and the peripheral flange portion 35b becomes the auxiliary yoke. As the value approaches 10, the attractive force of the permanent magnet 9 increases.
As the movable plunger 35 rises, the movable contact 25 connected via the shaft 36 rises. Accordingly, when contact pressure is applied by the contact spring 40, the first movable contact 25a and the second movable contact 25b of the movable contact 25 are respectively connected to the first fixed contact 23d of the first fixed contact 23 and the first fixed contact 23d. The second fixed contact 24 is in contact with each of the second fixed contacts 24d. After that, when the contact pressure of the contact spring 40 disappears, the movable contact 25 is in a contact opening start state in which the movable contact 25 is separated upward from the first fixed contact 23 and the second fixed contact 24.

In such a contact opening start state, the first movable contact 25a and the second movable contact 25b of the movable contact 25, and the first fixed contact 23d and the second fixed contact 24 of the first fixed contact 23 are second. An arc is generated between the fixed contact 24d and the current conduction state is continued by the arc.
This arc is extinguished by being stretched by the Lorentz force generated by the Fleming left-hand rule from the relationship between the current flow of the arc and the magnetic flux generated by the arc extinguishing permanent magnet (not shown).
When the releasing operation of the movable plunger 35 is completed, the upper surface of the peripheral flange portion 35b of the movable plunger 35 comes into contact with the lower surface of the auxiliary yoke 10, and the opening is completed.

(Second Embodiment)
Next, an electromagnetic contactor according to a second embodiment of the present invention will be described with reference to FIGS. 4 and 5, the same members as those shown in FIGS. 2 and 3 are denoted by the same reference numerals, and the description thereof may be omitted.
FIG. 4 shows a coupling state between the movable plunger and the shaft of the electromagnetic contactor according to the second embodiment of the present invention, and FIG. 5 shows the movable plunger and the shaft shown in FIG.
The basic configuration of the electromagnetic contactor according to the second embodiment of the present invention is the same as that of the electromagnetic contactor 1 according to the first embodiment shown in FIG. 1, but the configuration of the guide mechanism 37 is different.
That is, the guide mechanism 37 of the electromagnetic contactor 1 according to the first embodiment includes the movable plunger side first guide portion 35f and the movable plunger side second guide portion 35g formed on both sides of the female thread portion 35e of the shaft through hole 35c. And the shaft side first guide part 36c and the shaft side first part formed on both sides of the male thread part 36d of the shaft 36 and serving as an intermediate fit with respect to the movable plunger side first guide part 35f and the movable plunger side second guide part 35g. 2 guide portions 36e.

  In contrast, the electromagnetic contactor guide mechanism 37 according to the second embodiment of the present invention is coaxial with the shaft through hole 35c from the upper surface 35ba of the peripheral flange portion 35b of the movable plunger 35, as shown in FIG. It has a movable plunger side extension 35h projecting upward, and extends upward from a movable plunger side extension guide part 35fa formed above the female thread part 35e of the shaft through-hole 35c and a male thread part 36d of the shaft 36. It is comprised by the shaft side extension guide part 36f used as an intermediate fit with respect to the plunger side extension guide part 35fa. The fitting tolerance between the movable plunger side extension guide portion 35fa and the shaft side extension guide portion 36f is about h on the basis of the axis. The fit tolerance can be arbitrarily designed as long as it can suppress the inclination of the shaft 36 with respect to the movable plunger 35 and can be easily assembled. For example, a clearance fit of about g on the axis basis may be used, and an intermediate fit of about k or m on the axis basis may be used.

That is, at the center of the movable plunger 35, as shown in FIG. 4, a shaft through-hole 35c into which a shaft 36 formed in a round bar shape can be inserted extends downward from the upper surface of the movable plunger side extension 35h. The shaft through-hole 35c extends to reach the upper end surface of the return spring accommodating recess 35d. An internal thread portion 35e is formed below the shaft through hole 35c, and a movable plunger side extension guide portion 35fa is formed above the shaft through hole 35c.
On the other hand, on the lower side of the flange portion 36b of the shaft 36, as shown in FIG. 4, a male screw portion 36d that engages with the female screw portion 35e on the movable plunger 35 side is formed. Further, on the upper side of the male thread portion 36d of the shaft 36 and below the flange portion 36b, as shown in FIGS. 4 and 5, the shaft side serving as an intermediate fit with respect to the movable plunger side extension guide portion 35fa. An extension guide portion 36f is formed.

Then, when the female screw portion 35e of the movable plunger 35 is screwed into the male screw portion 36d of the shaft 36, the movable plunger side extension guide portion 35fa and the shaft side extension guide portion 36f become an intermediate fit. As a result, the length of the intermediate fit can be increased, so that the shaft center of the shaft 36 and the shaft center of the shaft through hole 35c are coaxial.
Then, after the female screw portion 35e of the movable plunger 35 is screwed into the male screw portion 36d of the shaft 36, the lower end portion of the shaft 36 and the upper end surface of the return spring accommodating recess 35d of the movable plunger 35 are joined together by welding to move the movable plunger 35. Is coupled to the shaft 36.
Here, since the shaft center of the shaft 36 and the shaft center of the shaft through-hole 35c are made coaxial by the guide mechanism 37, when the movable plunger 35 is coupled to the shaft 36, the inclination of the shaft 36 with respect to the movable plunger 35 is increased. Can be suppressed. Therefore, the first movable contact 25a and the second movable contact 25b are set to the wipe amount of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d. It is possible to suppress variations occurring between the two.

(Third embodiment)
Next, an electromagnetic contactor according to a third embodiment of the present invention will be described with reference to FIG. 6, the same members as those shown in FIG. 2 are denoted by the same reference numerals, and the description thereof may be omitted.
FIG. 4 shows a coupling state between the movable plunger and the shaft of the electromagnetic contactor according to the third embodiment of the present invention.
The basic configuration of the electromagnetic contactor according to the third embodiment of the present invention is the same as that of the electromagnetic contactor 1 according to the first embodiment shown in FIG. 42 is different.

  That is, the electromagnetic contactor according to the third embodiment is formed on the upper surface 35ba of the peripheral flange portion 35b of the movable plunger 35 as shown in FIG. 6 in addition to the guide mechanism 37 of the electromagnetic contactor 1 according to the first embodiment. A cylindrical coaxial function auxiliary member insertion portion 35 i in which a coaxial function auxiliary member insertion recess 35 j is formed is provided so as to surround the shaft 36. A coaxial function auxiliary member 42 that assists the coaxial function of the guide mechanism 37 is disposed in the coaxial function auxiliary member insertion recess 35 j and around the shaft 36. The coaxial function auxiliary member 42 is composed of an O-ring formed of an elastic member, and is arranged so that the outer peripheral side is in contact with the inner wall of the coaxial function auxiliary member insertion recess 35j and the inner peripheral side is in contact with the outer peripheral surface of the shaft 36. The

When the movable plunger 35 is coupled to the shaft 36, the shaft center of the shaft 36 and the shaft center of the through hole 35c for the shaft are made coaxial by the guide mechanism 37. By providing this coaxial function auxiliary member 42, In addition, the coaxial function by the guide mechanism 37 can be assisted. That is, the coaxial function auxiliary member 42 also makes the shaft center of the shaft 36 and the shaft center of the shaft through hole 35c coaxial.
Thereby, the coaxial function by the guide mechanism 37 is enhanced, and the inclination of the shaft 36 relative to the movable plunger 35 can be further suppressed when the movable plunger 35 is coupled to the shaft 36. Therefore, the first movable contact 25a and the second movable contact 25b are set to the wipe amount of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d. It is possible to further suppress variations occurring between the two.

(Fourth embodiment)
Next, an electromagnetic contactor according to a fourth embodiment of the present invention will be described with reference to FIG. In FIG. 7, the same members as those shown in FIG. 2 are denoted by the same reference numerals, and the description thereof may be omitted.
FIG. 7 shows a coupling state between the movable plunger and the shaft of the electromagnetic contactor according to the fourth embodiment of the present invention.
The electromagnetic contactor according to the fourth embodiment of the present invention has the same basic configuration as that of the electromagnetic contactor 1 according to the first embodiment shown in FIG. 1, but is different in that it includes a spring member.

  That is, the electromagnetic contactor according to the fourth embodiment includes, in addition to the guide mechanism 37 of the electromagnetic contactor 1 according to the first embodiment, an upper surface 35ba of the peripheral flange portion 35b of the movable plunger 35, as shown in FIG. A spring member 43 is disposed between the flange portion 36 b formed on the shaft 36 and around the shaft 36. The spring member 43 eliminates the gap between the male screw portion 36d of the shaft 36 and the female screw portion 35e of the movable plunger 35 by the spring force, and prevents the shaft 36 from being inclined with respect to the movable plunger 35 due to the gap. To do. In the present embodiment, the spring member 43 is constituted by a compression coil spring. When the spring member 43 is formed of a compression coil spring, the urging force of the compression coil spring acts on the movable plunger 35, and the movable plunger 35 moves downward by the gap, thereby eliminating the gap.

  By providing this spring member 43, in addition to the coaxial function by the guide mechanism 37, the clearance between the male threaded portion 36d of the shaft 36 and the female threaded portion 35e of the movable plunger 35 is eliminated by the spring force, so that the clearance is reduced. For this reason, the shaft 36 can be prevented from tilting with respect to the movable plunger 35, and when the movable plunger 35 is coupled to the shaft 36, the tilt of the shaft 36 with respect to the movable plunger 35 can be further suppressed. Therefore, the first movable contact 25a and the second movable contact 25b are set to the wipe amount of the first movable contact 25a and the second movable contact 25b at both ends of the movable contact 25 with respect to the first fixed contact 23d and the second fixed contact 24d. It is possible to further suppress variations occurring between the two.

As mentioned above, although embodiment of this invention has been described, this invention is not limited to this, A various change and improvement can be performed.
For example, in the first embodiment, the guide mechanism 37 includes a movable plunger side first guide portion 35f and a movable plunger side second guide portion 35g formed on both sides of the female thread portion 35e of the shaft through hole 35c, and the shaft 36. The shaft side first guide portion 36c and the shaft side second guide portion 36e formed on both sides of the male screw portion 36d are composed of three or more movable plunger side guide portions and intermediate fits thereto. You may comprise by the shaft side guide part which becomes.

Further, in the third embodiment, the coaxial function auxiliary member 42 is configured by an O-ring formed of an elastic member. However, as long as it assists the coaxial function by the guide mechanism 37, the coaxial function auxiliary member 42 is other than the O-ring. Also good.
Furthermore, in the fourth embodiment, the spring member 43 is configured by a compression coil spring, but may be configured by a tension coil spring.
Further, the coaxial function auxiliary member 42 in the third embodiment may be added to the guide mechanism 37 in the second embodiment.
The spring member 43 in the fourth embodiment may be added to the guide mechanism 37 in the second embodiment.

DESCRIPTION OF SYMBOLS 1 Electromagnetic contactor 2 Contact mechanism 3 Electromagnet unit 23 1st fixed contact (fixed contact)
23d First fixed contact (fixed contact)
24 Second fixed contact (fixed contact)
24d Second fixed contact (fixed contact)
25 Movable contact 35 Movable plunger 35ba Upper surface (one surface)
35c Shaft through-hole 35e Female thread portion 35f Movable plunger side first guide portion 35fa Movable plunger side extension guide portion 35g Movable plunger side second guide portion 35h Movable plunger side extension portion 35j Coaxial function auxiliary member fitting recess 36 Shaft 36b Flange portion 36c Shaft side first guide part 36d Male thread part 36e Shaft side second guide part 36f Shaft side extension guide part 37 Guide mechanism 42 Coaxial function auxiliary member 43 Spring member

Claims (5)

A contact mechanism having a pair of fixed contacts each having a fixed contact, and a movable contact capable of moving a movable contact at both ends of the fixed contact of the pair of fixed contacts;
An electromagnet unit that drives the contact mechanism, and has a movable plunger connected to the movable contact by a shaft;
A shaft through-hole through which the shaft can be inserted is formed in the movable plunger, and a female thread portion is formed in the shaft through-hole,
The shaft is formed with a male screw portion that is screwed into the female screw portion,
An electromagnetic contactor, wherein the movable plunger and the shaft are provided with a guide mechanism that coaxially aligns the axis of the shaft and the axis of the through hole for the shaft.   The guide mechanism is formed on at least both sides of the plurality of movable plunger side guide portions formed at least on both sides of the female screw portion of the shaft through hole, and on the both sides of the male screw portion of the shaft, and is provided on the movable plunger side guide portion. The electromagnetic contactor according to claim 1, further comprising a plurality of shaft side guide portions having a predetermined fit tolerance.   The guide mechanism has a movable plunger side extension that protrudes upward from the one surface coaxially with the shaft through-hole from one surface of the movable plunger, and is formed above the female screw portion of the shaft through-hole. A movable plunger side extension guide portion and a shaft side extension guide portion extending upward from the male thread portion of the shaft and having a predetermined fit tolerance with respect to the movable plunger side extension guide portion. The electromagnetic contactor according to claim 1.   A coaxial function auxiliary member insertion recess is formed in the movable plunger, and a coaxial function auxiliary member that assists the coaxial function by the guide mechanism is disposed in the coaxial function auxiliary member insertion recess and around the shaft. The electromagnetic contactor according to claim 2 or 3, characterized in that.   4. The electromagnetic contactor according to claim 2, wherein a spring member is disposed between one surface of the movable plunger and a flange portion formed on the shaft and around the shaft. 5.

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