JPH04245116A - Reed switch - Google Patents

Abstract

PURPOSE:To prevent one-sided transition of metal materials constituting contacts of a reed switch from one contact side to the other contact side so as to enhance reliability at low and middle loads. CONSTITUTION:A contact metal having hardness and melting point higher than those of a contact metal of a reed piece on a cathode side is used for a contact portion of the reed piece connected onto an anode side where heat generation is larger than in a contact portion of the reed piece connected onto the cathode side. Each melting state of the contact metals in the contact portions are made the same at low and middle loads. The contact metals are cut off almost in the middle portion between the contacts in the case of generation of a melting bridge.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to reed switches, and is particularly suitable for use in improving the reliability of reed switches operated by external magnetic fields.

0002

[Prior Art] As is well known, a reed switch is composed of two or three reed pieces sealed together with an inert gas in a container made of glass, ceramic, etc., and is operated by a magnetic field applied from the outside. . Conventionally, in a reed switch having such a configuration, gold is used as the base metal for the contact portion of each of the reed pieces, and the gold is coated with rhodium, ruthenium, or the like by plating. In this case, the same metal material was used for the lead piece connected to the anode and the lead piece connected to the cathode.

0003

[Problems to be Solved by the Invention] However, when the contact portions of the opposing reed pieces are made of the same metal material as in the past, the following disadvantages occur when the reed switch is operated. Ta. That is, when the contact is closed, the contact material softens or melts due to Joule heat, and a molten bridge occurs between both contacts, but in this case, the anode side becomes hotter than the cathode side due to the Thomson effect. Therefore, when the contacts are opened, the fused bridge is broken on the anode side.

[0004] Such a phenomenon occurs each time the contact is opened and closed, so if it is repeated several times, the contact material will transfer from the anode side contact to the cathode side contact. As a result, a depression is created on the contact surface on the anode side, and
Protrusions appear on the contact surface on the cathode side. If such depressions or protrusions are formed on the surface of each contact, there is a problem that the contact resistance value of the reed switch fluctuates or the contacts become unable to separate from each other. this is,
When a reed switch is operated under a low to medium load of DC 10V-1mA, the rate at which the contact metal melts on the anode side becomes larger than the rate at which the contact metal melts at the cathode side, and the difference in solubility between the two contact areas increases. This became especially noticeable as the size increased. In view of the above-mentioned problems, the present invention prevents the metal material constituting the contacts of a reed switch from unilaterally transferring from one contact side to the other, and operates under low and medium load conditions. The purpose is to improve reliability when

[0005]

[Means for Solving the Problems] The reed switch of the present invention seals an inert gas in a container made of glass, ceramic, etc., and connects one reed piece to the cathode side and the anode side. In the reed switch configured by arranging the other lead piece and the other lead piece facing each other in the container, a contact metal having high hardness and melting point is used for the contact part of the one lead piece connected to the cathode side, and A contact metal having a higher hardness and melting point than the contact metal used for the contact part of the one lead piece is used for the contact part of the other lead piece connected to the anode side. There is.

[0006]

[Function] The contact part of the lead piece connected to the anode side generates more heat than the contact part of the lead piece connected to the cathode side. By using a contact metal with a high melting point, the melting state of the contact metals in both contact parts is made to be the same when operated under low and medium load conditions. As a result, if a melt bridge occurs, it will be severed approximately at the center between these contacts, and the metal material forming the contacts will be prevented from being unilaterally transferred from one side to the other. .

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram of a reed switch showing an embodiment of the present invention. As is clear from FIG. 1, in the reed switch of this embodiment, the tip 1a of the first reed piece 1 and the tip 2a of the second reed piece 2 are spaced apart from each other by a predetermined distance in the glass tube 3. The glass tubes 3 are made to face each other, and an inert gas is sealed inside the glass tube 3. The reed switch of this embodiment configured in this manner is used as a make-type reed switch that is operated by an external magnetic field to open and close an electric circuit.

The first and second lead pieces 1 and 2 are
For example, it is made of iron-nickel alloy. Also,
A contact metal is adhered to the tip portions of each lead piece 1 and 2, that is, the contact portion. In this embodiment, a first contact metal a is deposited on the base of the tip portion 1a of the first lead piece 1, and a second contact metal b is deposited on the upper side thereof. These first and second contact metals are
Gold is used as the contact metal a, and rhodium is used as the second contact metal b, which are adhered to the tip 1a of the first lead piece 1 by plating. On the other hand, a third contact metal c is adhered to the tip portion 2a of the second lead piece 2. As this third contact metal c, tungsten, rhenium, etc. are used, and this is C
It is attached to the tip 2a of the second lead piece by VD.

As mentioned above, in the case of a conventional reed switch, the same type of contact material (for example, rhodium, etc.) is coated on the contact portions of the two opposing reed pieces. There was an inconvenience. However, in the case of the reed switch of this embodiment, the metal material of the contact part of the first lead piece 1 and the metal material of the contact part of the second lead piece 2 are made to have different softening temperatures, melting points, etc. The contact material attached to the tip 1a of the first lead piece 1 softens or melts more easily than the contact material attached to the tip 2a of the second lead piece 2. Therefore, by using the first lead piece 1 as a cathode and the second lead piece 2 as an anode, it is possible to make the softening or melting state of the contact materials of both poles the same when the contact is closed. Therefore, transfer of the contact material can be effectively prevented.

Next, a second embodiment of the present invention will be described in detail with reference to FIG. This second embodiment shows an example in which the present invention is applied to a break type reed switch. Contrary to the above-described make type, this type of reed switch is configured such that its contacts are normally closed and can be opened by removing the bias magnet 6. The type of contact metal is the same as in the case of the first embodiment, in which a first contact metal a is adhered as a base to the tip 1a of the first lead piece 1 used as a cathode, and a first contact metal No. 2 contact metal b is deposited. Also, the tip 2a of the second lead piece 2 used as an anode
A third contact metal c is adhered to.

FIG. 3 shows a transfer type reed switch that switches an electric circuit using an external magnetic field. The contact structure in this case is that the first lead piece 1 used as a cathode is the same as in the first and second embodiments. That is, the first contact metal a is deposited on the base, and the second contact metal b is deposited on the upper side thereof. On the other hand, the second lead piece 2 used as an anode
A third contact metal c is adhered to the third lead piece 13. In the contact portion of the third lead piece 13, a fourth contact metal d made of a copper-nickel alloy is interposed below the third contact metal c. this is,
It is arranged to form a gap for canceling the attraction force, and prevents the normally closed contact and the normally open contact from attracting each other.

FIG. 4 shows a make type reed switch similarly to FIG. 1, and in this case, the first and second lead pieces 1 and 2 are both coated with the first contact metal a on the base. It is worn. The tip 1a of the first lead piece 1 used as a cathode is coated with palladium, which is the fifth contact metal e, and the tip of the second lead piece 2 used as an anode is coated with palladium. 2a has a second contact metal b
is covered.

FIG. 5 shows an example in which the present invention is applied to a break type reed switch as in FIG. 2, and in this case as well, the first and second lead pieces 1, A first contact metal a is deposited on the base of each of the contacts 2 and 2, respectively. A first lead piece 1 is used as a cathode.
A fifth contact metal e is adhered to the tip portion 1a. Further, a second contact metal b is adhered to the tip portion 2a of the second lead piece 2 used as an anode.

FIG. 6 shows a transfer type reed switch which performs an electric circuit switching operation using an external magnetic field, similar to FIG. 3. The contact structure in this case is such that the first lead piece 1 used as a cathode has a first contact metal a coated on its base, and a fifth contact metal e coated on its upper side. . On the other hand, the tip 2a of the second lead piece 2 and the tip 13a of the third lead piece 13, which are used as anodes, have a first contact metal a coated on the base, and a first contact metal a on the upper side. Two contact metals b are respectively deposited. Also in this example, a fourth contact metal d for canceling the above-described attraction force is interposed below the second contact metal b at the tip 13a of the third lead piece 13.

In each of the reed switches shown in FIGS. 1 to 6, each lead piece 1, 2, 13 is
It may also be formed using an alloy consisting of cobalt-tungsten. By using the above alloy, once the contacts are closed by a magnetic field, they can remain closed even if the magnetic field is removed, and a self-holding reed switch can be created in which the contacts open when a reverse magnetic field is applied. Can be configured.

[0016]

Effects of the Invention As described above, the present invention has the advantage that the melting point of the contact metal material that adheres to the contact portion of the lead piece connected to the anode side is such that the melting point of the contact metal material adheres to the contact portion of the lead piece connected to the cathode side. The temperature is higher than the melting point of the contact metal material.
When the reed switch is operated under low to medium load conditions, the molten states of the contact metals in both contact portions can be made uniform. Therefore, when a molten bridge occurs between both contact portions, the molten bridge can be cut approximately at the center between these contacts, so that the metal material constituting the contact portion is removed from one of the contact portions. It is possible to effectively prevent unilateral transfer from one contact part to the other contact part, and it is possible to improve reliability when operating under low and medium load conditions.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram of a make type reed switch showing a first embodiment.

FIG. 2 is a configuration diagram of a break type reed switch showing a second embodiment.

FIG. 3 is a configuration diagram of a transfer type reed switch showing a third embodiment.

FIG. 4 is a configuration diagram of a make type reed switch showing a fourth embodiment.

FIG. 5 is a configuration diagram of a break type reed switch showing a fifth embodiment.

FIG. 6 is a configuration diagram of a transfer type reed switch showing a third embodiment.

[Explanation of symbols]

1 First lead piece 1a Tip 2 Second lead piece 2a Tip 3 Glass tube 6 Bias magnet 13 Third lead piece a First contact metal b Second contact metal c Third contact metal d Fourth contact metal e Fifth contact metal

Claims (4)

[Claims] Claim 1: A container made of glass, ceramic, etc. is sealed with an inert gas, and one lead piece connected to the cathode side and the other lead piece connected to the anode side are placed inside the container. In a reed switch configured to face each other, a contact metal with high hardness and a high melting point is used for the contact portion of one lead piece connected to the cathode side, and the other lead piece connected to the anode side A reed switch characterized in that a contact metal having a higher hardness and melting point than the contact metal used for the contact part of the one reed piece is used for the contact part of the reed switch. 2. A claim characterized in that the contact metal of one of the lead pieces connected to the cathode side is rhodium, and the contact metal of the other lead piece connected to the anode side is tungsten. Reed switch according to item 1. 3. A claim characterized in that the contact metal of one of the lead pieces connected to the cathode side is rhodium, and the contact metal of the other lead piece connected to the anode side is rhenium. Reed switch according to item 1. 4. A claim characterized in that the contact metal of one of the lead pieces connected to the cathode side is palladium, and the contact metal of the other lead piece connected to the anode side is rhodium. Reed switch according to item 1.