Motor actuated buzzer assembly with a plurality of leaf springs of different frequencies

Abstract

A motor actuated buzzer includes a motor mounted on a body, at least one cam member fixedly mounted on an output shaft of the motor, a sound generating plate mounted on the body, and a hammer for striking the sound generating plate, the cam having a plurality of radial protrusions. At least one leaf spring is fixed to the body at one end thereof and urged toward the cam member. The leaf spring carries the hammer intermediate opposite ends thereof and having at a free end thereof a projection. The radial protrusions are engageable with the projection upon rotation of the cam member to oscillate the leaf spring to intermittently bring the hammer into striking contact with the sound generating plate to produce a buzzing sound.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a motor actuated buzzer for an alarm device or a burglar alarm.

2. Prior Art

One conventional buzzer comprises an electromagnet adapted to be excited by either a DC current or an AC current, a sound generating plate, an oscillatory plate carrying a hammer and attracted by the electromagnet to move toward the sound generating plate to bring the hammer into striking contact with the sound generating plate, and a switching means having a first contact mounted on the oscillatory plate and a second contact mounted on a buzzer body, the first contact being moved away from the second contact when the oscillatory plate is moved toward the sound generating plate to de-energize the electromagnet. With this conventional buzzer, the spacing between the first and second contacts as well as the spacing between the oscillatory plate and the electromagnet need to be accurately predetermined so that the oscillatory plate can be operated properly to produce a buzzing sound of a desired volume.

The conventional buzzer has the following disadvantages:

(a) When the buzzer is used over a long period of time, the oscillatory plate, the electromagnet and the sound generating plate become displaced with respect to one another since the buzzer is subjected to vibration during the operation, so that the spacing between the electromagnet and the oscillatory plate as well as the spacing between the first and second contacts is changed. As a result, the volume of the buzzing sound produced may be varied, and in the worst case the oscillatory plate fails to produce a buzzing sound,

(b) A delicate adjustment is required in assembling the buzzer so that the above-mentioned component parts are accurately positioned with respect to one another.

(c) When the buzzer is used in those places, such as a factory and a plant, where a power voltage for the buzzer is subjected to a fluctuation, the oscillatory movement of the oscillatory plate tends to becomes unstable or to be stopped.

(d) When the oscillatory plate is used for a long period of time, it is subjected to fatigue and may finally be subjected to damage or breakage.

SUMMARY OF THE INVENTION

It is therefore an object of this invention to provide a motor actuated buzzer which can produce a buzzing sound of a desired volume for a long period of time in a stable manner, requires no delicate adjustment when assembling the buzzer, and is not affected by a fluctuation in the power voltage.

According to the present invention, there is provided a motor actuated buzzer comprising:

(a) a body;

(b) a motor mounted on the body and having a rotatable output shaft;

(c) cam means comprising at least one cam member fixedly mounted on the output shaft and having a plurality of radial protrusions;

(d) a sound generating plate mounted on the body;

(e) a hammer for striking the sound generating plate; and

(f) resilient means comprising at least one leaf spring fixed to the body at one end thereof and urged toward the cam member, the leaf spring carrying the hammer intermediate opposite ends thereof and having at a free end thereof a projection, the radial protrusions being engageable with the projection upon rotation of the cam member to oscillate the leaf spring to intermittently bring the hammer into striking contact with the sound generating plate to produce a buzzing sound.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view of a motor actuated buzzer provided in accordance with the present invention;

FIG. 2 is a plan view of a motor housing;

FIG. 3 is a side elevational view of the housing;

FIG. 4 is a bottom view of the housing;

FIG. 5 is a cross-sectional view of the housing;

FIG. 6 is a fragmentary side elevational view of the buzzer, showing the engagement of a leaf spring with a cam;

FIG. 7 is a perspective view of a modified leaf spring assembly;

FIG. 8 is an diagramatical illustration showing characteristics of the leaf spring assembly of FIG. 7

FIG. 9 is a view similar to FIG. 7 but showing another modified leaf spring assembly;

FIG. 10 is a fragmentary perspective view of a modified buzzer;

FIG. 11 is a bottom view of a motor housing of the modified buzzer;

FIG. 12 is a perspective view of a mounting plate of another modified buzzer;

FIG. 13 is a cross-sectional view of a housing of said another modified buzzer; and

FIG. 14 is an exploded perspective view of a portion of a further modified buzzer showing a leaf spring and a cam.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

A motor actuated buzzer 10 shown in FIG. 1 comprises a casing or body 12 of a rectangular shape having a front wall 12a and an open rear 12b, the front wall 12a having a number of apertures 12c for efficiently transmitting a buzzing sound. A rectangular frame 14 of a square cross-section is fitted in and secured to the casing 12, the frame 14 having a plurality of pins 14a formed on a surface thereof facing away from the front wall 12a and having four holes 14b formed in that surface at four corners thereof.

A sound generating plate 16 of a rectangular shape is made of metal such as an aluminum alloy having a central circular raised portion 16a drawn out of the plane of the plate 16, the sound generating plate 16 having a plurality of apertures 16b formed therethrough at a marginal portion thereof and four apertures 16c formed through four corners thereof. The sound generating plate 16 is received in the casing 12 with the pins 14a passing through the apertures 16b, respectively.

A stamped mounting plate 18 of a rectangular shape is made of metal such as iron and has a generally rectangular opening 18a and an L-shaped support portion 20 defined by a first leg 20a extending perpendicularly from a marginal portion thereof and a second leg 20b extending perpendicularly from the first leg 20a at its distal end. The mounting plate 18 has a plurality of apertures 18c formed through a marginal portion thereof and four apertures 18d formed through four corners thereof. A pair of spaced hollow pins 22 are formed on the second leg 20b of the L-shaped support portion 20. The mounting plate 18 is received in the casing 12 and mated with the sound generating plate 16 with the pins 14a passing through the apertures 18c and pressed at their free ends to join the frame 14, the sound generating plate 16 and the mounting plate 18 together, the raised portion 16a extending through the opening 18a. A rear plate or lid (not shown) is attached to the rear of the body 12 by screws (not shown) passing through respective aligned apertures 18d and 16c into the holes 14b.

A generally rectangular leaf spring 24 constituting resilient means is made of a resilient material such as steel and has at one end a pair of apertures 24a through which the hollow pins 22 extend and pressed at their free ends to hold the leaf spring 24. The free end of the leaf spring 24 is reduced in width and has a transverse projection 24b of an arcuate cross-section convex toward the mounting plate 18. A cylindrical hammer member 26 made of plastics material or the like has one end of a reduced diameter passing through an aperture 24c in the leaf spring 24 and a washer 28 and fused at a free end thereof to fix it to the leaf spring 24.

A DC motor 30 having a rotatable output shaft 30a is housed in a housing 32 of plastics material, and the leaf spring 24 is disposed transversely of the output shaft 30a. As best shown in FIGS. 2 to 5, the housing 32 has a generally cylindrical body composed of a pair of semi-cylindrical shells 32a and 32b connected together at their one lateral marginal portions by a hinge 34. The shells 32a and 32b have respective pawls or engaging means 36a and 36b formed integrally on the other lateral marginal portions in opposed relation to each other. Formed through the mounting plate 18 is a square retaining aperture 18f into which the opposed pawls 36a and 36b are snappingly fitted to fix the housing 32 with respect to the mounting plate 18.

A cam 40 in the form of a generally pentagonal plate is fixedly mounted on the output shaft 30a, and an arcuate recess 40a is formed in each of the five sides of the cam 40 and disposed between each adjacent corner portions 40b serving as radial protrusions. The radius of curvature of each recess 40a is greater than that of the arcuate projection 24b of the leaf spring 24, and therefore the projection 24b is spaced from the bottom of the recess 40a when it is received in the recess 40a, as shown in FIG. 6. The free end of the leaf spring 24 resiliently engages the outer periphery of the cam 40, and upon rotation of the cam 40, the leaf spring 24 is caused to oscillate or move between an operative position shown in a solid line in FIG. 6 where the arcuate projection 24b is received in the recess 40a to allow the hammer 26 to strike the raised portion 16a of the sound generating plate 16 and an inoperative position shown in a dash- and-dot line where the arcuate projection 24b engages the corner portion 40b to move the hammer 26 away from the raised portion 16a. By virture of the provision of the arcuate projection 24b, the amplitude of oscillation of the leaf spring 24 is increased. The edge into which each recess 40a and each corner portion 40b merge is chamfered or made smooth to prevent an undue resistance from developing between the edge and the arcuate projection 24b during the operation of the buzzer 10.

A holder member 42 of an L-shaped cross-section is secured to the mounting plate 18 by screws (not shown), the holder member 42 having a first leg 42a disposed perpendicular to the mounting plate 18 and a second leg 42b extending perpendicular to the first leg. An arm 42c extends from the second leg 42b in coplanar relation thereto to hold the housing 32. A set screw 44 is threaded through the second leg 42b and is engageable with the oscillating leaf spring 24 to limit its retracting movement away from the mounting plate 18. With this construction, the volume of the buzzing sound can be changed by adjusting the tightening of the set screw 44.

In the above embodiment, although the frame 14 including the pins 14a is made of metal such as aluminum, they may be formed of plastics material, in which case the free ends of the pins 14a are fused to connect the frame 14, the sound generating plate 16 and the mounting plate 18 together. The use of the plastics material frame 14 contributes to the production of a buzzing sound of a more mild tone. The arcuate projection 24b of the leaf spring 24 is formed by stamping but may be formed by securing a separate projection element to a flat free end.

According to a modified form of the invention shown in FIG. 7, two additional leaf springs 48 and 50 are mated with the opposite sides of the leaf spring 24 and extend along the length thereof. The pair of hollow pins 22 extend through the apertures 50a, 24a and 48a of the leaf springs 50, 24 and 48. The leaf spring 48 has substantially the same length as the leaf spring 24 while the leaf spring 50 terminates short of the hammer 26. As shown in FIG. 8, the leaf springs 24 and 48 have different natural frequencies f0 and f1, so that the combined frequency of the leaf spring assembly has a wider band as indicated in a dash-and-dot line in FIG. 8. Therefore, even if a power voltage for powering the motor 30 is subjected to a fluctuation to vary the rotation of the motor, the buzzer 10 can always produce a buzzing sound in a stable manner. In addition, the leaf springs can be used for a longer period of time. In this embodiment, the leaf spring 50 may be omitted.

According to another modified form of the invention shown in FIG. 9, a leaf spring 51 is mated with one side of the leaf spring 24 facing away from the hammer 26, the leaf spring 51 extending along the length of the leaf spring 24 only to the proximal end of the free end of a reduced width. This leaf spring assembly can achieve effects similar to the leaf spring assembly shown in FIG. 7.

A further modified form of the invention shown in FIG. 10 differs from the embodiment of FIG. 1 in that a row of four retaining means or apertures 52a to 52d are formed through the mounting plate 18 and in that a first cam 56 of a pentagonal shape similar to the cam 40 and a second cam 54 of a square shape are fixedly mounted on the output shaft 30a of the motor 30 and are spaced along a length thereof. FIG. 11 is a bottom view of a motor housing 32' which is identical to the motor housing 32 except that two pairs of pawls 36a and 36b are formed on the bottom of shells 32a and 32b, the opposed pawls 36a and the opposed pawls 36b being spaced along the length of the housing 32'. The distance between the first and third retaining apertures 52a and 52c is equal to the distance between the second and fourth retaining apertures 52b and 52d. And, the distance between the first and second cams 54 and 56 is equal to the distance between the first and second apertures 52a and 52b.

With this construction, the housing 32' can be selectively mounted on the mounting plate 18 in either a first mounting position or a second mounting position. More specifically, in the first mounting position, the opposed pawls 36a and the opposed pawls 36b are snappingly fitted in the first and third retaining apertures 52a and 52c, respectively, to fix the housing 32' to the mounting plate 18, so that the first cam 54 is so positioned as to be engaged with the free end of the leaf spring 24. On the other hand, in the second mounting position, the opposed pawls 36a and the opposed pawls 36b are snappingly fitted in the second and fourth retaining apertures 52b and 52d, respectively, so that the second cam 56 is so positioned as to be engaged with the free end of the leaf spring 24. The first cam 54 of a pentagonal shape can produce a buzzing sound of a higher tone than the second cam 56 of a square shape. Since the housing 32' is mounted on the mounting plate 18 through the snap fit of the pawls 36a and 36b in the retaining apertures, the housing 32' can be easily changed from the first to the second mounting position and vice versa even on-site.

A still further modified form of the invention shown in FIG. 12 differs from the embodiment shown in FIG. 10 in that the mounting plate 18 has only a pair of retaining apertures 52a and 52b, that a motor housing 32' (FIG. 13) has only a pair of pawls 36a which are snappingly fitted in the retaining apertures 52a and 52b, and that a first pair of apertures 56a and a second pair of apertures 56b are formed through a second leg 20b of a support member 20 and are spaced along the length of the output shaft 30a of the motor 30. With this construction, the leaf spring 24 can be mounted in either a first mounting position or a second mounting position. More specifically, in the first mounting position, the apertures 24a of the leaf spring 24 are aligned with the first pair of apertures 56a with screws (not shown) passing respectively through these aligned apertures to fix the leaf spring 24 to the mounting plate 18, so that the first cam 54 engages the free end of the leaf spring 24. On the other hand, in the second mounting position, the apertures 24a of the leaf spring 24 are aligned with the second pair of apertures 56b with the screws passing respectively through these aligned apertures, so that the second cam 56 engages the free end of the leaf spring 24.

A further modified form of the invention shown in FIG. 14, differs from the embodiment of FIG. 1 in that a first cam 54 of a pentagonal shape and a second cam 56 of a sqaure shape are fixedly mounted on the output shaft 30a of the motor 30 and that a leaf spring 24 is of a generally U-shape having a pair of spaced arms 24d and 24e each having an arcuate projection 24b at its free end. A hammer 26 is secured to each of the arms 24d and 24e. The free ends of the arms 24d and 24e resiliently engage the first and second cams 54 and 56, respectively. With this construction, the two hammers 26 are brought into striking engagement with the sound generating plate 16 to produce two kinds of sounds different in frequency from each other, so that a composite sound having a beat frequency of the two frequencies is produced.

Claims

1. A motor actuated buzzer comprising:

(a) a body;

(b) a motor mounted on said body and having a rotatable output shaft;

(c) cam means comprising at least one cam member fixedly mounted on said output shaft and having a plurality of radial protrusions;

(d) a sound generating plate mounted on said body;

(e) a hammer for striking said sound generating plate; and

(f) resilient means comprising a plurality of leaf springs placed one upon the other, each of said springs being fixed to said body at one end thereof and urged toward said cam member, one of said leaf springs carrying said hammer intermediate opposite ends thereof and having at a free end thereof a projection, said radial protrusions being engageable with said projection upon rotation of said cam member, said plurality of leaf springs having such different frequencies that, when said cam member rotates, said plurality of leaf springs cooperate with one another to oscillate as a combined leaf spring which is wider in bandwidth than any one of said plurality of leaf springs, whereby said sound generating plate is intermittently struck by said hammer to produce a buzzing sound.

2. A buzzer according to claim 1, in which said cam means comprises a plurality of cam members fixedly mounted on said output shaft and spaced along a length thereof, said plurality of cam members having different numbers of radial protrusions, and one of said resilient means and said cam means being adjustable to be displaced with respect to the other in the direction of the length of said output shaft so that said projection is engageable with said radial protrusions of one of said cam members.

3. A buzzer according to claim 1, in which said cam means comprises a plurality of cam members fixedly mounted on said output shaft and spaced along a length thereof, said plurality of cam members having different numbers of radial protrusions, said buzzer comprising a plurality of said resilient means corresponding respectively to said plurality of cam members and spaced along the length of said output shaft, said buzzer further comprising a plurality of said hammers corresponding respectively to said plurality of said resilient means, each of said projections provided respectively in said plurality of resilient means being engageable with a respective one of said plurality of cam members.

4. A buzzer according to claim 2, further comprising a mounting plate mounted on said body and having a row of retaining means, and a housing holding said motor therein with said output shaft extending exteriorly thereof, said resilient means being supported on said mounting plate, said housing having engaging means detachably engageable with a selected one of said retaining means.

5. A buzzer according to claim 4, in which said retaining means comprises a row of apertures formed through said mounting plate, said engaging means comprising at least one pair of pawls engageable with said aperture.

6. A buzzer according to claim 1, in which said cam member has a polygonal shape having an arcuate recess in each side thereof, said projection being of an arcuate shape convex toward said cam member and being receivable in said recess in each side of said polygonal cam member.