CA2008021C - High sensitivity door edge switch - Google Patents

Abstract

A high sensitivity door edge switch used with a door having an edge for response to a low unit pressure applied over a large portion of the door edge. The door switch comprise an inner element extending along the edge of the door having one face proximate the door edge, a resiliently compressible perforate spacer in facing relation with the other face of the inner element, the spacer including a plurality of spaced perforations extending generally perpendicular to said inner element, and having a relatively greater elastic compressibility than said inner element. A substantially imperforate outer element is in facing relation with the spacer remote from said inner element, said outer element having a relatively greater elastic compressibility than said spacer, said outer element being elastically deformable into the spacer perforations toward the inner element upon low unit pressure being applied over a large portion of the outer element and a pair of relatively flexible conductive elements located on opposite sides of said spacer and positioned respectively between the spacer and said inner and outer elements, said conductive elements being in spaced confronting relation through said spacer perforations in the absence of said low unit pressure and upon application of said low unit pressure to said outer element, at least one of said conductive elements deflecting into engagement with the other of said conductive elements by the elastic deformation of said outer element into all the spacer perforations encompassed by said large portion of the door edge.

Description

3~

HIGH SENSITIVITY
DOOR EDGE SWITCH

BACRGROUND OF THE INVENTION
The high sensitivity door edge switch of the present invention is particularly concerned with safety edges and auto-matic stop switches for doors, such as overhead doors, public conveyance doors, wherein the door isautomatically operated and ; I;it is desired to quickly, safely and reliably stop tand reverse, i~if required) door operation responsive to relatively low external pressure applied to the leading door edge, even if the external pressure is dispersed to effectively reduce its unit value. Of cour.se, the instant door edge switch is capable of many varied applications, all of which are intended to be comprehended herein.
Illustrative of the-prior art of which applicant is aware are the below listed patents:
U.S. Patent No. Patentee 3,243,540 Miller ; 3,462,885 Miller 3,754,176 Miller 4,090,045 ~arsh 4,137,116 Miller 4,200,777 Miller 4,349,710 ~iller 4,362,911 Sears 4,396,814 Miller 2it~ ),'2:1 In prior art switches of this general type, there was ,required a highly locali~ed deflection to ~ate the switch. Even a substantial force or weight may not have been sufficient to actuate a prior art switch, if the force or weight was distributed .over a substantial area. In an attempt to obviate this problem, prior art devices often included internal protrusions for locally enhancing internal forces reacting to an external weight. This structure added to cost of materials, complexity of manufacture, and often inhibited or reduced flexibility to require additional space in shipping and storage.

SUMMARY OF THE INVE~ITION
It is among the important objects of the present inven-tion to provide an electric door edge switch which overcomes the above mentioned dif~iculties, being highly sensitive to force or pressure imparted to the switch, being responsive to broadly applied forces rather than requiring highly localized forces, and which pe~mits of fa~rication from substantially flat material for economy in manufacture, flexibility in installation, and compact-ness in storage and shipment.
It-is a further object of the present invention to provide a doo:r edge switch which is of relativel~ high sensitivity so as to permit of relatively stiff external materials for en~
hanced wear resistance without detracting from switch sensitivity.
Other objects of the present invention will become apparent upon reading the following specification and referring to the accompanying drawings, which form a material part of this disclosure.

The invention accordingly consists in the features of construction, combinations of elements, and arrangements of parts, which will be exemplified in the construction hereinafter describ-ed, and of which the so~ will be indicated by the appended claims.
BRIEF DESCRIPTION OF THE DRA~INGS
Fig. 1 is a front elevational view showing an overhead door having an edge switch in accordance with the teaching of the present invention.
Fig. 2 is a transverse sectional view taken generally along the line 2-2 of Fig. 1.
Fig. 3 is an enlarged, broken away view showing ele-ments of the door edge of Fig. 2.
Fig. 4 is a longitudinal sectional view taken generally along the line 4-4 of Fig. 2 with the door edge switch in a distended or at rest condition.
Fig. 5 is a longitudinal sectional view similar to Fig. 4, but illustrating the door edge switch in a pressurized, electrically contacting condition~
Fig. 6 is a longitudinal sectional view similar to Fig. 4, bu~ showing a slightly modified embodiment wherein the more co~pressible and elastically deformable element is inward toward the door edge.
Fig. 7 is a longitudinal sectional view similar to Fig. 6, but illustrating the ~bodiment thereof in a pressurized, electrically contacting condition.
D~S~K1~1'ION OF THE PP~FERRED EMBODI~ENT
Referring now more particularlv to the drawings, and specifically to Fig. 1 thereof, a building wall is there desig-nated 10, having formed therein a door opening or way 11. A door 12 is shown in the doorway 11 closing the same. The door 12 maybe ~ 0 ~

of the vertically moving or overhead type having along its lower or leading edge a high sensitivity door edge switch of the present invention generally designated 15. Of course, the door 12 may be of other types, for example a horizontally moving door, as in an elevator, bus or the like, having a vertical leading or closing edge provided with a switch of the present invention.
In Fig. 2 is shown the door 12~ provided along its lower edge 16 with the door edge switch lS of the invention. The internal construction of the door edge switch 15 is best seen in Fig. 3, as including an elongate inner element 17, such as a strip~
of foam extending closely along an~ in facing relation with the leading door edge 16. As illustrated the strip or inner element 17 may be of a width approximately laterally coextensive with the thickness of door 12; and while the inner element 17 may be fabri-cated of plastic foam, or the like, it may be relatively dense so as to be characterized by relative hardness or of relatively low elastic compressibility, as will appear more fully hereinafter.
The inner element 17 may be substantially longitudi-nally coextensive with the door edge 16, or of less extent if conditions require.
Immediately below and in facing relation with the inner ele~ent 17 is an intermediate spacer element or strip 20 which may be substantiallly coe~tensive in width and length with the inner element 17, and substantially congruent therewith. The intermedi-ate ele~ent or spacer 20 is of an open work or perforated configu-ration, having a series of through holes or perforations 21. The spacer strip 20 may also be fabricated of plastic foam, and may be of a hardness equal to or less than that of the inner element 17, as by heing of a density eaual to or less than that of the inner 3~

element. In practice, the spacer 20 is advantageously of at least some resilient compressibility, while the inner element 17 is not necessarily resiliently compressible.
Tr~e~;ately beneath the spacer 20, and substantially congruent therewith, is an outer elongate strip or deflection element 24, also advantageously fabricated of plastic foam. The outer or deflection element 24 is similarly of width and length so as to be horizontally co-extensive with the outline configuration of spacer 20 and inner element 17.
The outer or deflection element 24 is relatively less dense that the spacer 20 so as to be relatively highly elastically~
com~ressible, having an elastic compressibility of at least 1.5 times that of the spacer 20. As will appear more fully herein-after, the resilient compressibility of the deflection element 24 is sufficiently greater than that of the spacer 20 for resilient protrusion of the deflection element through the ~erforations 21 of the spacer under vertical compression of the assembly between hori-zontal planes.
Interposed in sandwiched relation between the inner ele-ment 17 and the spacer 20 is a highly flexibly compliant electri-cally conductive element 25, say aluminum foil or equivalent which may be carried by a backing sheet 26 of highly flexible compliant material~ such zs plastic sheeting or film~ The conductive element 25 overlies the several apertures 21, facing downwardly theleU~ yl~
A similar highly flexible and compliant element 27 is carr~ed ~ a highly flexible backing sheet 28, which are together sandwiched in interposed relation between the spacer 20 and upper side of t~e outer or deflection element 24, ~ith the conductive element 27 uppermost and facing upwardly through aper~ures 21.

sa~ ~' Thus, the conductive elements 25 and 27 are on opposite sides of the spacer 20 in spaced confro:nting relation through the perfora-tions 21 in the condition show:n in Figs. 2, 3 and 4 - The assembled elements of Fig. 3 are suitably enclosed in a flexible moisture and vapor proof tubular casing 30, see ;Fig. 2, and an additional, generally U-shaped enclosure 31 may surround the sides and bottom of the casing 30 with its edges 32 : secured to the door 12. Thus, the generally tubular inner casing 30 protectively encloses the herebefore described operative ele-ments, and the outer enclosure 31 serves to mount the assembly to the door 12. The inner and outer casings 30 and 31 may also be fabricated of flexible plastic sheeting. In conventional manner, the conductive element 25 and 27 may be connected by leads, as at 32 and 33 in Fig. 4, for electrical connection to suitable con-trol circuitry, such as a control relay for a motor, or other.
- While safety edges in the past generally required ~ substantial localized pressure to displace the normally spaced ~ contacts into engagement, it was sometimes possible to engage the .
. sa~ety edge over a large extend o~ its length with a substantial total force and not close or engage the switch contacts. That is, the substantial total p.ressure against tha switch is dispersed over a large area so as to be o~ insufficient unit pressure to effec~
- the desired operation.
Howe~er, by the instant invention the resilient com-pressibility of the aeflection element 24 and the spacer 20 are selected so that even under low unit pressure applied to the under-side of the switch 15, the de~lection element is elastically deformed into the perforations 21 of the spacer toward the inner element 17, so that the flexible conductive element, and ~articu-larly the element 27, is displaced into the perforations 21 for electrical eonnection between the conductive element. The condi-tion is shown in Fig. 5. Switch operation may serve in many ways, for example,-to deactivate an electric motor operating to close the door, as upon obstruction in the path of door movement, or upon completed door closure.
In practice, it has been found entirely satisfactory to employ a deflection element 24 having an elastic compressibility of about twice that of the sPaCer 20 to insure sensitivity under a wide range of conditions. Also, the size of the spacer perfora-tions 21 are advantageously selected of a sufficiently small diameter for resilient protrusion o~ the deflection element 24 through the perforations without p~rm~nent deformation of the conductive elements 25 and 27 in contact with each other.
Referring now to the embodiment of Figs. 6 and 7, the door is there generally designated 12a, and the high sensitivity door edge switch of the present invention is generally designated l5a. The door ~dge switch 15a may be essentially similar to the door edge switch 15, but the more compressible and elastically deformable switch element is located proximate to the door edge 16a, rather than remote from the door edge, as in the first described embodiment.
More particularly, an elongate inner foam ele~ent 17a, such as a strip of foam extends closely along and in facing rela-tion with the leading door edge 16a and may be relatively less dense so as to be characterized by relatively high com~ressibility and elastic deformability.

Immediately below and in fac~relation with the inner element 17a is an intermediate spacer element or strip 20a which is of an openwork or perforatecl configuration having a series of through holes or perforations 21a. The spacer strip 20a may also be fabricated of plastic foam and may be of a hardness greater than that of the inner element 17a, as by being of greater density than the inner element.
Immediately beneath the spacer 20a is an outer elongate strip or element 24a, also advantageously fabricated of plastic j' foam. The inner element 17a, spacer 20a and outer element 24a may - all be of similar width and length so as to be substantially horizontally coextensive with each other.
The outer element 24a is, in this embodiment, of rela-tively high density, so as to be relatively rigid, for enhanced durability of the assembly.
However, the resilient compressibility of the inner element 17a is sufficiently greater .han that of the spacer 20a ~or resilient protrusion of the inner element through the perforations 21a of the spacer under vertical compression of the assembly between horizontal planes.
Interposed between the spacer 20a and each of the inner element 17a and outer element 24a is a highly flexible and com-pliant electrically conductive element, as at 25a and 27a, res-nectively. The conductive elements may be of all~m;num foil or other suitably flexible and conductive material, and may be reinforced by backing sheets, such as of plastic film, as at 26a and 28a. Thus, the conductive elements 25a and 27a are on opposite sides of the spacer 20a and in spaced confronting relation with each other through the perforations 21a in the at rest condition ~ 3 shown in Fig. 6.
As in the first described embodiment, the several foam layers are encased in a flexible moisture and vapor proof tubular casing 30a and an additional, generally U-shaped enclosure 31a having its edges secured to the door 12a. Also, the conductive elements 25a and 27a may be electrically connected, as by leads 32a and 33a for electrical connection to suitable control cir-cuitry.
By this embodiment there is provided a stiffer, more durable outer element 24a for increased durability, as in certain industrial conditions where safety is not sacrificed for this improved durability. In contrast, the first described embodiment may be employed, as in elevators, mass transit doors, or the like where relatively soft outer elements are more safely presented to passing personnel. However, in both embodiments there is pro-vided the enhanced sensitivity resulting from the relatively different com~ressibilities of the different layers.
From the f&~e~Ding, it is seen that the present inven-tion provides a high sensitivity door edge switch which is rela-tiYely simPle in construction and economical in manufacture, being capable of utilization in many widely varying condition, and which otherwise fully acco~plishes its intended objects.
Although the present invention has been described in some detail bv way of illustration and example for purposes of clarity of understanding, it is understood that certain changes and modifications may be made within the spirit of the invention.

Claims (12)

1. A high sensitivity door edge switch used with a door having an edge for response to a low unit pressure applied over a large portion of the door edge, said door switch comprising, an inner element extending along the edge of said door having one face proximate the door edge, a resiliently compressible perforate spacer in facing relation with the other face of said inner element, said spacer including a plurality of spaced perforations extending generally perpendicular to said inner element, said spacer having a relatively greater elastic compressibility than said inner element, a substantially imperforate outer element in facing relation with said spacer remote from said inner element, said outer element having a relatively greater elastic compressibility than said spacer, said outer element being elastically deformable into the spacer perforations toward the inner element upon low unit pressure being applied over a large portion of the outer element and a pair of relatively flexible conductive elements located on opposite sides of said spacer and positioned respectively between the spacer and said inner and outer elements, said conductive elements being in spaced confronting relation through said spacer perforations in the absence of said low unit pressure and upon application of said low unit pressure to said outer element, at least one of said conductive elements deflecting into engagement with the other of said conductive elements by the elastic deformation of said outer element into all the spacer perforations encompassed by said large portion of the door edge.

2. A high sensitivity door edge switch according to claim 1, at least one of said conductive elements being of aluminum foil.

3. A high sensitivity door edge switch according to claim 1, wherein said inner and outer elements are constructed of foam.

4. A high sensitivity door edge switch according to claim 1, wherein said outer element has an elastic compressibility of about twice that of said spacer to insure sensitivity under a wide range of conditions.

5. A high sensitivity door edge switch according to claim 1, wherein said inner and outer elements and said spacer are fabricated of foam.

6. A high sensitivity door edge switch according to claim 1, said perforate spacer having perforations sufficiently small for resilient protrusion of said outer element without permanent deformation of said conductive element into contact.

7. A high sensitivity door edge switch according to claim 1, said inner element, spacer and outer element all being substantially flat in undistended condition.

8. A high sensitivity door edge switch according to claim 1, the compressibility of said outer element being sufficiently greater than that of said spacer for resilient protrusion of said outer element through the spacer to contact said conductive elements upon movement of the remote surfaces of said inner and outer elements in parallelism toward each other.

9. A high sensitivity door edge switch according to claim 1, said outer element and spacer being fabricated of foam, and the foam of said outer element having an elastic compressibility of at least 1.5 times that of the foam of said spacer.

10. A high sensitivity door edge switch used with a door having an edge for response to a low unit pressure applied over a large portion of the door edge, said door edge switch comprising, an inner element extending along the edge of said door, having once face proximate the door edge, a resiliently compressible perforate spacer in facing relation with the other face of said inner element, said spacer including a plurality of spaced perforations extending generally perpendicular to said inner element, said inner element having a relatively greater elastic compressibility than said spacer, a substantially imperforate outer element in facing relation with said spacer remote from said inner element, said spacer having a relatively greater elastic compressibility than said outer element, said inner element: being elastically deformable into the spacer perforations toward the outer element upon low unit pressure being applied over a large portion of the outer element and a pair of relatively flexible conductive elements located on opposite sides of said spacer and positioned respectively between the spacer and said inner and outer elements, said conductive elements being in spaced confronting relation through said spacer perforations in the absence of said low unit pressure and upon application of said low unit pressure to said outer element, at least one of said conductive elements deflecting into engagement with the other of said conductive elements by the elastic deformation of said inner element into all the spacer perforations encompassed by the large portion of the door edge.

11. A high sensitivity door edge switch according to claim 10, the compressibility of said inner element being sufficiently greater than that of said spacer for resilient protrusion of said inner element through the spacer to contact conductive elements upon movement of the remote surfaces of said inner and outer element in parallelism toward each other.

12. A high sensitivity door edge switch according to claim 10, said inner element and spacer being fabricated of foam, and the foam of said inner element having an elastic compressibility of at least 1.5 times that of the foam of said spacer.