US2178151A - Relay contact spring - Google Patents

Relay contact spring Download PDF

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Publication number
US2178151A
US2178151A US165019A US16501937A US2178151A US 2178151 A US2178151 A US 2178151A US 165019 A US165019 A US 165019A US 16501937 A US16501937 A US 16501937A US 2178151 A US2178151 A US 2178151A
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spring
tongues
relay
springs
contact
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Expired - Lifetime
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US165019A
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Harold N Wagar
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H1/00Contacts
    • H01H1/50Means for increasing contact pressure, preventing vibration of contacts, holding contacts together after engagement, or biasing contacts to the open position

Definitions

  • FIG 5B FIG. 4A 5 5 /4 1 PM E FIG. Z4
  • This invention relates to relays and more particularly to relay contact springs.
  • relays In electric circuits generally and in telephone circuits particularly relays are extensively employed. In such circuits the functions to be performed are numerous and varied and it is often very essential that relays employed in such circuits shall positively make and break the circuits controlled over their contacts. If the contacts of a relay do not make firmly or break cleanly, or in other words, if the contacts have a tendency to chatter when they make or break, false operation in the circuits controlled thereover will result.
  • each spring is in effect a reed fixedly supported at one end and free at the other end, any motion imparted to the free end, either through the operation of the relay armature or through the vibration of the support upon which the relay is mounted, will tend to cause the spring to vibrate at a periodicity determined by its free length, by the location and form of any supports along its length, and with an amplitude determined by the force applied thereto. It has been determined by experimentation that the vibration of a relay spring can be materially reduced by making the spring self-damping or with a large internal energy dissipation.
  • This object is attained in accordance with the present invention by shearing the springs to form tongues having a different periodicity than that of the springs as a whole, which tongues may be staked to or have their ends in frictional engagement with the body of the springs, or in the case of the passive or spoolhead springs, providing damping pads or other damping media on the tangs of the springs which are engaged in the. spoolhead notches.
  • Figs. 1 to 3, inclusive, show. relay springs having tongues sheared therein, Fig. 1 showing two tongues sheared from the spring along its axial line, Fig. 2 showing a single long tongue sheared from the spring along its axial line and Fig. 3 showing tongues sheared from the spring along its two edges;
  • Figs. 4A to 7A, inclusive show different methods of shearing the contact ends of spring blanks to form tongues while the corresponding Figs. 43 to '73, inclusive, show the tongues bent into their final positions in which the tongues of each spring are in frictional engagement;
  • Fig. 8 shows the front spoolhead of a relay in the notches of which the tangs of springs are engaged, a damping medium being interposed between the tangs and the notches;
  • Fig. 9 shows a plan view of one of the springs disclosed in Fig. 8 with a damping medium applied to the spoolhead tang thereof;
  • Figs. 10 and 11 show respectively a plan view and a side elevation of the end of a spring with the spoolhead tang thereof bent to provide damping between the spring and a notch of the spoolhead.
  • relay contact springs which are rendered self-damping by shearing the body of the springs in such a manner as to form tongues.
  • Each spring I is provided with the usual terminal lug 2, holes 3 through which screws may extend for clamping the spring to the relay heel-piece'or mounting bracket and tang I for engagement in a notch of the front spoolhead and contacts 5.
  • two tongues 6 located along the axial line of the spring are sheared from the spring in the portion thereof located between the mounting holes 3 and the tang 4, or between the rear support of the spring on the heel-piece and the front support on the spoolhead.
  • the spring of Fig. 2 is similarly sheared to form a single long tongue I, while the spring of Fig. 3 is sheared adjacent to its edges to form four tongues 8.
  • the tongues of 6, I or 8 may be free to vibrate except as restrained by the frictional resistance between their edges and the adjacent edges of the body of the springs, or may be staked to the body of the springs as indicated by the dots 9.
  • the shearing has been illustrated as applied to the passive or spoolhead springs of a relay, it is to be understood that similar shearing might also be applied to the active or armature operated springs.
  • the short tongues formed by the shearing process will have different fiexural characteristics than the springs as a whole, since the bending moments tending to pro Jerusalem flexure of the main body of the springs will not act on the tongues except through frictional contact between the edges of the tongues and the main body of the springs.
  • the frictional forces between the tongues and spring bodies during the resulting flexure will tend to give the springs a large internal dissipation which will render them self damping.
  • the contact carrying end of the spring may be formed with tongues the ends of which are in frictional or rubbing engagement.
  • Figs. 4A to 7A, inclusive show spring blanks stamped in different designs to provide such tongues and the corresponding Figs. 43 to 78, inclusive, show such blanks after the tongues have been bent into their final positions.
  • the tip of each spring I is divided or split and each section thus formed carries a contact 5.
  • each end section of the spring I is stamped to provide a pair oi. tongues l0 and H after which the tongues II are bent as shown in Fig. 413 so that their ends overlap and engage the ends of tongues I0.
  • the end of the spring is stamped to form a central section, or tongue l2, and a contact carrying section on either side thereof, each of the latter sections having an inwardly extending tongue I0. so formed is then bent, as shown in Fig. 53, with the ends of tongues l0 overlapping and engaging the central tongue l2.
  • the spring blank may be stamped as shown in Fig.
  • the spring blank may be stamped as shown in Fig. 7A with a tongue l4 extending inwardly from the inner edge of each end section of the spring. The end sections are then bent toward each other into the position shown in Fig. 7B in which position the tongues l4 overlap and engage each other. It will, of course, be apparent that the springs might be stamped out in designs not herein illustrated, to form tongues which could be bent to overlap and engage with each other.
  • the end sections carrying separate contacts tend to vibrate independently of each other and through the rubbing engagement between the tongues formed thereon, mutually damp each other and thereby reduce the tendency of the contacts carried thereby to make a chattering engagement with the contacts of mate springs.
  • the spoolhead or passive springs of a relay may be made self-damping by the application of a damping medium to the spring tangs 4 at their point of engagement in the notches of the front spoolhead.
  • This embodiment of the invention is illustrated in Figs. 8 to 11, inclusive. Referring to Figs. 8 and 9, the front spoolhead of a relay is shown at l 5 provided with notches IS in the edge thereof in which the tangs 4 of the passive contact springs I! are engaged. A cooperating armature or active spring is shown at 18.
  • each passive spring is provided with a surrounding pad I9 which may be of energy absorbing material such as cork, cellulose acetate sheet, or fabric treated with such substances as cellulose acetate, varnish or rubber.
  • a surrounding pad I9 may be of energy absorbing material such as cork, cellulose acetate sheet, or fabric treated with such substances as cellulose acetate, varnish or rubber.
  • the padding material may be made in tubular form.
  • the spoolhead tangs of the springs may be bent into a spring loop, as illustrated at 20 in Figs. 10 and 11, so that the tang when inserted into the spoolhead notch will entirely fill the notch.
  • the spring blank 1 In a relay, a contact spring having portions sheared therein for increasing the internal dissipation of mechanical vibration imparted to said spring.
  • a contact spring having a tongue sheared therein, said tongue being in frictional engagement with another portion of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • contact spring having a tongue sheared from the body thereof, the edges of said tongue being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring having a plurality of tongues sheared from the body thereof, the edges of said tongues being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • contact spring having a plu rality of tongues sheared from the edges thereof, the inner edges of said tongues being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring having a tongue sheared therein, the edges of said tongue being staked to the adjacent edges of the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring having a plurality of tongues sheared therein, the edges of said tongues being staked to the adjacent edges of the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring having its contact tip sheared to form tongues, said tongues being bent to overlap each other with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said .spring is increased.
  • a contact spring having its contact tip divided into two sections and tongues formed on each section, said tongues being bent to overlap with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring having its contact tip divided into two sections and tongues formed on each section, the tongues of each section overlapping each other with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
  • a contact spring a notched member positioned adjacent to the free end of said spring, a tang extending laterally from said spring into a notch of said member, and vibration damping means on said tang for engagement with the walls of said notch.
  • a contact spring In a relay, a contact spring, a notched member positioned adjacent to the free end of said spring, a tang extending laterally from said spring into a notch of said member, and a vibration damping pad surrounding said tang for engagement with the walls of said notch.

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Description

Oct. 31, 1939. H. N. WAGAR RELAY CONTACT SPRING Filed Sept. 22, 1957' FIG] 5% E FIG. 2
FIG 5B FIG. 4A 5 5 /4 1 PM E FIG. Z4
mun/70 By H/V. WAG/1R Q 6. M
ATTORNEY Patented Oct. 31, 1939 UNITED STATES RELAY CONTACT SPRING Harold N. Wagar, New York, N. Y., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application September 22, 1937, Serial No. 165,019
12 Claims.
This invention relates to relays and more particularly to relay contact springs.
In electric circuits generally and in telephone circuits particularly relays are extensively employed. In such circuits the functions to be performed are numerous and varied and it is often very essential that relays employed in such circuits shall positively make and break the circuits controlled over their contacts. If the contacts of a relay do not make firmly or break cleanly, or in other words, if the contacts have a tendency to chatter when they make or break, false operation in the circuits controlled thereover will result.
It has been found that one of the factors which contributes to the tendency of relay contacts to chatter is the inherent vibratory action of the springs. Since each spring is in effect a reed fixedly supported at one end and free at the other end, any motion imparted to the free end, either through the operation of the relay armature or through the vibration of the support upon which the relay is mounted, will tend to cause the spring to vibrate at a periodicity determined by its free length, by the location and form of any supports along its length, and with an amplitude determined by the force applied thereto. It has been determined by experimentation that the vibration of a relay spring can be materially reduced by making the spring self-damping or with a large internal energy dissipation.
It is therefore the object of the present invention to reduce the chattering of relay contacts by rendering the springs which carry the contacts self-damping.
This object is attained in accordance with the present invention by shearing the springs to form tongues having a different periodicity than that of the springs as a whole, which tongues may be staked to or have their ends in frictional engagement with the body of the springs, or in the case of the passive or spoolhead springs, providing damping pads or other damping media on the tangs of the springs which are engaged in the. spoolhead notches.
It is believed that the invention will be more readily understood from the following detailed description taken in connection with the accompanying drawing in which:
Figs. 1 to 3, inclusive, show. relay springs having tongues sheared therein, Fig. 1 showing two tongues sheared from the spring along its axial line, Fig. 2 showing a single long tongue sheared from the spring along its axial line and Fig. 3 showing tongues sheared from the spring along its two edges;
Figs. 4A to 7A, inclusive, show different methods of shearing the contact ends of spring blanks to form tongues while the corresponding Figs. 43 to '73, inclusive, show the tongues bent into their final positions in which the tongues of each spring are in frictional engagement;
Fig. 8 shows the front spoolhead of a relay in the notches of which the tangs of springs are engaged, a damping medium being interposed between the tangs and the notches;
Fig. 9 shows a plan view of one of the springs disclosed in Fig. 8 with a damping medium applied to the spoolhead tang thereof; and
Figs. 10 and 11 show respectively a plan view and a side elevation of the end of a spring with the spoolhead tang thereof bent to provide damping between the spring and a notch of the spoolhead.
Referring first to Figs. 1 to 3, inclusive, relay contact springs are disclosed which are rendered self-damping by shearing the body of the springs in such a manner as to form tongues. Each spring I is provided with the usual terminal lug 2, holes 3 through which screws may extend for clamping the spring to the relay heel-piece'or mounting bracket and tang I for engagement in a notch of the front spoolhead and contacts 5. In the spring disclosed in Fig. 1, two tongues 6 located along the axial line of the spring are sheared from the spring in the portion thereof located between the mounting holes 3 and the tang 4, or between the rear support of the spring on the heel-piece and the front support on the spoolhead. The spring of Fig. 2 is similarly sheared to form a single long tongue I, while the spring of Fig. 3 is sheared adjacent to its edges to form four tongues 8.
The tongues of 6, I or 8 may be free to vibrate except as restrained by the frictional resistance between their edges and the adjacent edges of the body of the springs, or may be staked to the body of the springs as indicated by the dots 9. Although the shearing has been illustrated as applied to the passive or spoolhead springs of a relay, it is to be understood that similar shearing might also be applied to the active or armature operated springs.
By thus shearing the springs, the short tongues formed by the shearing process will have different fiexural characteristics than the springs as a whole, since the bending moments tending to pro duce flexure of the main body of the springs will not act on the tongues except through frictional contact between the edges of the tongues and the main body of the springs. Thus, when the springs vibrate, the frictional forces between the tongues and spring bodies during the resulting flexure will tend to give the springs a large internal dissipation which will render them self damping.
As an alternative to the shearing of the body of the spring, the contact carrying end of the spring may be formed with tongues the ends of which are in frictional or rubbing engagement.
Figs. 4A to 7A, inclusive, show spring blanks stamped in different designs to provide such tongues and the corresponding Figs. 43 to 78, inclusive, show such blanks after the tongues have been bent into their final positions. As is common practice, the tip of each spring I is divided or split and each section thus formed carries a contact 5.
As illustrated in Fig. 4A, each end section of the spring I is stamped to provide a pair oi. tongues l0 and H after which the tongues II are bent as shown in Fig. 413 so that their ends overlap and engage the ends of tongues I0. As illustrated in Fig. 5A, the end of the spring is stamped to form a central section, or tongue l2, and a contact carrying section on either side thereof, each of the latter sections having an inwardly extending tongue I0. so formed is then bent, as shown in Fig. 53, with the ends of tongues l0 overlapping and engaging the central tongue l2. As a further alternative construction, the spring blank may be stamped as shown in Fig. 6A with a tongue I3 on only one of the end sections of the spring, which section is then bent, as shown in Fig. 6B, so that the tongue I3 thereof overlaps and engages the other end section of the spring. As a still further alternative construction, the spring blank may be stamped as shown in Fig. 7A with a tongue l4 extending inwardly from the inner edge of each end section of the spring. The end sections are then bent toward each other into the position shown in Fig. 7B in which position the tongues l4 overlap and engage each other. It will, of course, be apparent that the springs might be stamped out in designs not herein illustrated, to form tongues which could be bent to overlap and engage with each other.
With the spring tips thus divided into end sections, the end sections carrying separate contacts tend to vibrate independently of each other and through the rubbing engagement between the tongues formed thereon, mutually damp each other and thereby reduce the tendency of the contacts carried thereby to make a chattering engagement with the contacts of mate springs.
As afurther embodiment of the invention, the spoolhead or passive springs of a relay may be made self-damping by the application of a damping medium to the spring tangs 4 at their point of engagement in the notches of the front spoolhead. This embodiment of the invention is illustrated in Figs. 8 to 11, inclusive. Referring to Figs. 8 and 9, the front spoolhead of a relay is shown at l 5 provided with notches IS in the edge thereof in which the tangs 4 of the passive contact springs I! are engaged. A cooperating armature or active spring is shown at 18. The tang 4 of each passive spring is provided with a surrounding pad I9 which may be of energy absorbing material such as cork, cellulose acetate sheet, or fabric treated with such substances as cellulose acetate, varnish or rubber. For convenience of manufacture and assembly on the tangs, the padding material may be made in tubular form.
As an alternative, the spoolhead tangs of the springs may be bent into a spring loop, as illustrated at 20 in Figs. 10 and 11, so that the tang when inserted into the spoolhead notch will entirely fill the notch.
What is claimed is:
The spring blank 1. In a relay, a contact spring having portions sheared therein for increasing the internal dissipation of mechanical vibration imparted to said spring.
2. In a relay, a contact spring having a tongue sheared therein, said tongue being in frictional engagement with another portion of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
3. In a relay, 9. contact spring having a tongue sheared from the body thereof, the edges of said tongue being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
4. In a relay, a contact spring having a plurality of tongues sheared from the body thereof, the edges of said tongues being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
5. In a relay, 2. contact spring having a plu rality of tongues sheared from the edges thereof, the inner edges of said tongues being in frictional engagement with the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
6. In a relay, a contact spring having a tongue sheared therein, the edges of said tongue being staked to the adjacent edges of the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
7. In a relay, a contact spring having a plurality of tongues sheared therein, the edges of said tongues being staked to the adjacent edges of the body of said spring whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
8. In a relay,a contact spring having its contact tip sheared to form tongues, said tongues being bent to overlap each other with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said .spring is increased.
9. In a relay, a contact spring having its contact tip divided into two sections and tongues formed on each section, said tongues being bent to overlap with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
10., In a relay, a contact spring having its contact tip divided into two sections and tongues formed on each section, the tongues of each section overlapping each other with a frictional engagement whereby the internal dissipation of mechanical vibration imparted to said spring is increased.
11. In a relay, a contact spring a notched member positioned adjacent to the free end of said spring, a tang extending laterally from said spring into a notch of said member, and vibration damping means on said tang for engagement with the walls of said notch.
12. In a relay, a contact spring, a notched member positioned adjacent to the free end of said spring, a tang extending laterally from said spring into a notch of said member, and a vibration damping pad surrounding said tang for engagement with the walls of said notch.
HAROLD N. WAGAR.
US165019A 1937-09-22 1937-09-22 Relay contact spring Expired - Lifetime US2178151A (en)

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Cited By (14)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2487604A (en) * 1945-09-21 1949-11-08 Gen Electric Vibratory converter switch
US2501155A (en) * 1944-05-04 1950-03-21 Metals & Controls Corp Thermostatic circuit breaker
US2630692A (en) * 1948-05-04 1953-03-10 Walter E Naugler Flexible coupling
US2647962A (en) * 1950-01-11 1953-08-04 Ark Les Switch Corp Switch for electric ranges
US2755356A (en) * 1950-11-21 1956-07-17 Jucker Julius Electromagnetic relays
US2800535A (en) * 1954-08-30 1957-07-23 Bell Telephone Labor Inc Contact springs
US2810026A (en) * 1953-12-02 1957-10-15 Vigren Sten Daniel Electric switching devices
US2823271A (en) * 1955-10-20 1958-02-11 Edwin M Wagstaff Electric multiple switch
US3103847A (en) * 1959-04-10 1963-09-17 Chester A Raymond Capture-type combination action for organs
US3182159A (en) * 1960-04-19 1965-05-04 Claesson Per Harry Elias Contact spring group for relays, change-over switches and the like
US3319033A (en) * 1960-04-19 1967-05-09 Claesson Per Harry Elias Contact spring group for electrical switching apparatus
US3401453A (en) * 1966-05-27 1968-09-17 Sunbeam Corp Electric dry shaver
EP0777250A3 (en) * 1995-11-30 1997-10-15 Hella Kg Hueck & Co Electromagnetic relay with rockable armature
US20080258366A1 (en) * 2007-04-17 2008-10-23 Erick Tuttle Spring apparatus and a method of providing such

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2501155A (en) * 1944-05-04 1950-03-21 Metals & Controls Corp Thermostatic circuit breaker
US2487604A (en) * 1945-09-21 1949-11-08 Gen Electric Vibratory converter switch
US2630692A (en) * 1948-05-04 1953-03-10 Walter E Naugler Flexible coupling
US2647962A (en) * 1950-01-11 1953-08-04 Ark Les Switch Corp Switch for electric ranges
US2755356A (en) * 1950-11-21 1956-07-17 Jucker Julius Electromagnetic relays
US2810026A (en) * 1953-12-02 1957-10-15 Vigren Sten Daniel Electric switching devices
US2800535A (en) * 1954-08-30 1957-07-23 Bell Telephone Labor Inc Contact springs
US2823271A (en) * 1955-10-20 1958-02-11 Edwin M Wagstaff Electric multiple switch
US3103847A (en) * 1959-04-10 1963-09-17 Chester A Raymond Capture-type combination action for organs
US3182159A (en) * 1960-04-19 1965-05-04 Claesson Per Harry Elias Contact spring group for relays, change-over switches and the like
US3319033A (en) * 1960-04-19 1967-05-09 Claesson Per Harry Elias Contact spring group for electrical switching apparatus
US3401453A (en) * 1966-05-27 1968-09-17 Sunbeam Corp Electric dry shaver
EP0777250A3 (en) * 1995-11-30 1997-10-15 Hella Kg Hueck & Co Electromagnetic relay with rockable armature
US5864269A (en) * 1995-11-30 1999-01-26 Hella Kg Hueck & Co. Electromagnetic hinged-armature relay
US20080258366A1 (en) * 2007-04-17 2008-10-23 Erick Tuttle Spring apparatus and a method of providing such

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