Surface mounted door check device

Abstract

A surface-mounted device for controlling the swing/rotational motion of a hinged door/panel system. Said device controls the velocity of the door/panel's and provides check point(s) in the pathway of its motion. The device includes a non-pivoting carrier component to be fixed upon a hinged door/panel, a non-pivoting receiver component fastened to the adjacent and separate area which shares a common hinge(s)/axis with the movable door/panel and a flexible control arm component firmly attached at one end to the carrier. The flexible control arm is aligned with the receiver's through-body aperture by means of the carrier's fixed position on a movable hinged door/panel and provides control of the door/panel by means of passing into and through the aperture provisioned in the receiver in a linear manner to provide both speed and positional check control (motion detents) of the door's potential swing arc path. The speed control aspect of the device is accomplished by means of controlled frictional contact between the flexible control arm's component material(s) and the receiver's aperture and this effect is enhanced by means of the temporary physical deformation exhibited by the flexible control arm whilst it is undergoing loading stresses as it passes within the constriction of the receiver's aperture geometry, its component materials and the energized spherical element acting upon the wide surface of the flexible control arm by limiting frictional contact between the flexible control arm and the receiver's aperture when the energized spherical element is not engaged with the flexible control arm's provisioned negative areas(s) and the attached door/panel is in motion. Maximum frictional force is delivered by the device when the spherical element engages a provisioned negative area on the flexible control arm, thus creating a check in the door/panel swing path. The device may be added/retrofitted to the surfaces of a pre-existing or new hinged door/panel system without significant design or structural modifications of said hinged door/panel systems and their associated components.

Claims

1. A surface mounted door check device, comprising: a receiver body for attachment to a frame, the receiver body comprising a cavity having a first portion and a second portion, a compression spring and a spherical element contained within the cavity first portion such that the spherical element is biased toward the cavity second portion; a carrier for attachment to a door; a flexible control arm having a first end and a second end, the first end of the flexible control arm fixedly attached to the carrier such that the first end of the flexible control arm moves together with the carrier, the second end of the flexible control arm comprising a plurality of openings extending slidably through the cavity second portion; a stop block for limiting a maximum range of movement of the flexible control arm with respect to the receiver body, the stop block comprising a through slot for receiving the second end of the flexible control arm, and further comprising tool-free fasteners for removably connecting the stop block to the second end of the flexible control arm; and wherein movement of the door with respect to the frame moves the carrier and the first end of the flexible control arm such that the second end of the flexible control arm slides through the cavity second portion, each of the plurality of openings corresponding to a respective check position when a respective one of the plurality of openings is aligned with the spherical element.

2. The surface mounted door check device of claim 1, wherein the compression spring and spherical element exert friction upon the flexible control arm as the flexible control arm travels through the cavity second portion of the receiver body for controlling a relative speed between the door and frame.

3. The surface mounted door check device of claim 1, wherein the flexible control arm has a body with a rectilinear shape having a length, width, and thickness.

4. The surface mounted door check device of claim 1, wherein a portion of the spherical element is inserted into the plurality of openings in the flexible control arm in a direction extending 90 degrees with respect to a plane of the flexible control arm.

5. The surface mounted door check device of claim 1, wherein the flexible control arm is composed of a high-pressure fiberglass laminate or carbon fiber composite material.

6. The surface mounted door check device of claim 1, wherein the stop block prevents unwanted withdrawal of the flexible control arm from the receiver body.

7. The surface mounted door check device of claim 1, wherein the stop block is composed of a shock absorbing material.

8. The surface mounted door check device of claim 1, wherein the plurality of openings are circular-shaped.

9. The surface mounted door check device of claim 1, wherein the plurality of openings are rectangular-shaped.

10. The surface mounted door check device of claim 1, wherein the plurality of openings are ovoid teardrop-shaped.

11. The surface mounted door check device of claim 1, wherein the plurality of openings comprises three openings.

12. The surface mounted door check device of claim 1, wherein the plurality of openings comprises four openings.

13. The surface mounted door check device of claim 1, wherein the receiver body further comprises mounting holes.

14. The surface mounted door check device of claim 13, wherein the mounting holes of the receiver body are spaced apart and configured to align with existing fasteners of the frame.

15. The surface mounted door check device of claim 1, wherein the receiver body further comprises an aperture configured to accommodate the stop block.

16. The surface mounted door check device of claim 1, wherein the spherical element is formed of a metallic alloy, compression formed powdered metal, phenolic, or plastic material.

17. The surface mounted door check device of claim 1, wherein the spherical element is lubricous.

18. The surface mounted door check device of claim 1, further comprising a flanged bushing having a non-flanged end inserted within an inner diameter of the compression spring and a flanged end configured to engage the spherical element.

19. The surface mounted door check device of claim 18, wherein the flanged bushing comprises a self-lubricated material.

20. The surface mounted door check device of claim 1, wherein the carrier comprises a recess on a rear side for accommodating a pre-existing door retention strap.

21. The surface mounted door check device of claim 1, wherein the carrier comprises mounting holes, wherein the mounting holes of the carrier are spaced apart and configured to align with existing fasteners of the door.

Description

A BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 Is a perspective view of the preferred embodiment of the invention as it may be applied to a door 11a and chassis 11.

(2) FIG. 2 is a cross-section schematic top view of the receiver body 1, as well as, the flexible control arm 4, a spherical element 12, a compression spring 5, a flanged bushing 8, receiver covers 2 and fasteners 3.

(3) FIG. 3 is an exploded, isometric view of the receiver.

(4) FIG. 4 Is a top view of the invention as it may be applied to a door 11a, chassis 11 and hinge 9 that are in a primarily closed position.

(5) FIG. 5 illustrates the same parts as described in FIG. 4 and the door 11a, by way of rotation upon the hinge 9 is now seen in at least a partially open position.

(6) FIG. 6 Illustrates examples of two possible conditional positional states which are labeled as drawings p1 and p2 of the components contained within the receiver 1 when they may interact with the linear motion of the flexible control arm 4 and its provisioned negative areas 4a.

(7) FIG. 7 Is an isometric view of the underside, that partial portion of the carrier 6 which may make contact with a pre-existing surface(s) and showing features 6a and 6d which are negative spaces provisioned within the carrier's 6 body associated bracket 14 further lessens the need for the use of an optional door limiting stop block 15 as seen in FIG. 9

(8) FIG. 8 Shows five possible configuration examples of negative spaces which may be provisioned for the flexible control arm 4. As labeled, negative areas illustrated are door 11a swing check points for the invention. Said examples are illustrated and labeled as v1, v2, v3, v4 and v5.

(9) FIG. 9 Is an isometric view of the invention in an unmounted state.

DESCRIPTION OF THE PREFERRED EMBODIMENT

(10) FIG. 1 Is a perspective view of the preferred embodiment of the invention as it may be applied to a door 11a and chassis 11, which is shown in a partially open position as viewed from the interior of a vehicle. The door 11a rotates about a fixed axis upon a pre-existing hinge assembly 9, the axis of which is ostensibly parallel with the nearest edges of the pre-existing chassis 11 and the pre-existing door 11a.

(11) In this embodiment of the invention, the flexible control arm 4 is fixed to the carrier 6 with fasteners 10, which is in turn, fixed to a door 11a with fasteners 7 and bridges across the door 11a, hinge 9 and into the receiver 1, which is fixed to the chassis 11. The installed position of the invention is reversible, wherein the receiver body 1 may be fixed to a door 11a and the carrier 6 with the fixedly attached flexible control arm 4 which may be attached to the chassis 11 without a loss of functionality.

(12) Check points for control of the door 11a, to which the invention may be installed upon, the swing of which, is controlled, at least in part, via the negative spaces 4a as provisioned within the body of the flexible control arm 4. The size, shape and spacing of these negative spaces 4a may be determined by the requirements of the specific application as well as the user's preferences.

(13) The receiver body 1 is enclosed with two receiver covers 2 which are attached to opposing sides of the receiver's body 1 with fastener parts labeled 3, 3a and 3b. The fastening(s) may be of any suitable type or nature to address the needs of the application and/or the ease of manufacturability of the invention and all that entails.

(14) FIG. 2 is a cross-section schematic top view of the receiver body 1, as well as, the flexible control arm 4, a spherical element 12, a compression spring 5, a flanged bushing 8, receiver covers 2 and fasteners 3. In this view the negative space feature 4a of the flexible control arm 4 is aligned with the energized spherical element 12 which is located at this point of its travel through the receiver's 1 negative area 1a, thus creating a check, which may also be described as a point of higher than normal friction within the system's operational parameters. Located within the receiver's 1 negative area labeled 1b are components nearest the viewer in descending vertical order, the compression spring 5, the flanged bushing 8, the spherical element 12 and the flexible control arm 4.

(15) The flanged bushing 8 which may have a self-lubricating property, is placed between the spherical element 12 and the compression spring 5 acts and may act as an anti-friction bearing facilitating potential, and desirous property of rotational motion of the spherical element 12 as the flexible control arm 4 may pass in a linear direction beneath its surface. Said component group is oriented in a perpendicular geometry in relation to one of the two widest faces of the flexible control arm 4. This arrangement may place the energized spherical element 12 in alignment and in forced contact with the potential travel pathway of the flexible control arm 4 and, in particular, with its provisioned negative spaces 4a. The flexible control arm 4 is held in alignment with the aforementioned components within a boundary 1a formed as a negative spatial feature within the carrier body 1 and primarily and generally rectangularly shaped through-slots 2a which are provisioned in the receiver covers 2.

(16) FIG. 3 is an exploded, isometric view of the receiver body 1 exhibiting a cavity defined by, and as seen in this drawing viewpoint as, a primarily vertical negative section which is marked as area 1b and of which, when assembled, partially encloses the spherical element 12 which is located, as illustrated, at the lowest point within this area, the flanged bushing 8 rests immediately both above and upon the spherical element 12 and at the top of this described area is the compression spring 5. The outer, non-flanged diameter of the bushing 8 is designed so as to be inserted within the inner diameter of the compression spring 5 with the lowest portion of the compression spring 8 retained by the top surface of flanged section of said bushing 8.

(17) The lower section of negative area 1b of the receiver 1 is shown as being of a primarily horizontal area in appearance and is marked as area 1a. Negative area 1a will be occupied primarily, when assembled, by the flexible control arm 4. The negative area 1a, as aforementioned, extends through the receiver body 1.

(18) Enclosing the receiver body 1 are two receiver covers 2 which may be provisioned with thru-holes 2b which align with and receiver 1 provisioned thru-holes 1c in the receiver body 1. Alignment of the aforementioned negative spaces 2b and 1c facilitates the use of mechanical fastener components 3, 3a, 3b, 3c and 3d which pass through all three of these components, namely two of receiver covers 2 and one receiver body 1, to constrain and assist in containing the compression spring 5, the flanged bushing 8 and the spherical element 12 as an aligned assembly within the receiver body 1. The two receiver covers 2 are also provisioned with negative through-holes 2a which generally align with negative area 1a in the receiver body.

(19) The receiver body 1 is may also be provisioned with through-holes 1d which may allow mechanical fasteners 13 to attach the receiver body 1 to a chassis, of any manner, as illustrated in FIG. 1. The design of, or the provisioning of, said through-holes is dependent on the particular application and/or facilitating the ease of manufacture of the invention and its associated componentry.

(20) FIG. 4 Is a top view of the invention as it may be applied to a door 11a, chassis 11 and hinge 9 that are in a primarily closed position. We see, herein, the carrier 6 and the flexible control arm 4 which may be fixedly attached by means of mechanical fasteners 10 and the carrier body 6 is affixed to the pre-existing door 11a with fasteners 7. When said door 11a and chassis 11 are in this closed position it should be noted that the flexible control arm 4 is primarily straight in shape and in alignment with negative spaces 2a as provisioned in the carrier covers 2 and also with 1a as a negative space within the receiver body 1.

(21) FIG. 5 illustrates the same parts as described in FIG. 4 and the door 11a, by way of rotation upon the hinge 9 is now seen in at least a partially open position. It should be noted that the flexible control arm 4, which is fixedly attached to the carrier body 6, is now distorted into an arc shape by the rotation of the door 11a. Said rotation of the door 11a has increased the base distance between the carrier body 6 in relation to the receiver body 1 and the flexible control arm 4 which has been positioned into the receiver body 1 by means of the provisioned space 1a as seen in FIG. 3.

(22) FIG. 6 Illustrates examples of two possible conditional positional states which are labeled as drawings p1 and p2 of the components contained within the receiver 1 when they may interact with the linear motion of the flexible control arm 4 and its provisioned negative areas 4a. Said linear motion is the result of a converted and conveyed rotational motion of the door 11a as it may be rotated on the hinges 9 in relation to the receiver 1 when said receiver 1 is, or may be, utilized as a stationary element in the invention being fixedly mounted to the chassis 11.

(23) Both illustrations p1 and p2, show through-holes 1c, which may be provisioned wherein the use of mechanical fasteners 3, 3a, 3c and 3d may be desirable. The use of and/or style and nature of said fasteners is variable as to the application of the invention or its ease of manufacture.

(24) In illustration p1 we see a cross-sectional view of the receiver body 1 and the flexible control arm 4 with the compression spring 5 in its most compressed state as the flexible control arm 4 is occupying negative space 1a in the receiver body 1 but has not yet reached a potential check position 4a as provisioned on the flexible control arm 4. In this positional state, the spherical element 12 is riding on the primary positive (non-negative) surface of the flexible control arm 4.

(25) The second illustration of FIG. 6 is p2 which Is a cross-sectional view of the receiver body 1 and the flexible control arm 4 with the compression spring 5 in its most distended state. This new state of relationship between the aforementioned parts of the invention is also known as a check state and is the result of the flexible control arm 4 having travelled in a linear manner within negative space 1a and with the spherical element 12 having travelled vertically into a negative space 4a which may be provisioned on the flexible control arm 4 by means of the of the stored energy in the compression spring 5.

(26) FIG. 7 Is an isometric view of the underside, that partial portion of the carrier 6 which may make contact with a pre-existing surface(s) and showing features 6a and 6d which are negative spaces provisioned within the carrier's 6 body. The spaces labeled 6a and 6d are designed so that may facilitate the integration with and incorporate the use of a pre-existing door limiting strap 14a and its pre-existing door limiting strap bracket 14 over which the carrier body 6 may be placed. In this feature 6a the fasteners 7 may secure both the carrier body 6 and the pre-existing door limiting strap bracket 14 to a door 11a as seen in FIG. 1. Door limiting straps 14a are common on vehicles which feature removable doors and it may be desirable to maintain the existing door limiting strap 14a as it often carries electrical wiring within. Maintaining the existing limiting door strap 14a and its associated bracket 14 further lessens the need for the use of an optional door limiting stop block 15 as seen in FIG. 9

(27) FIG. 8 Shows five possible configuration examples of negative spaces which may be provisioned for the flexible control arm 4. As labeled, negative areas illustrated are door 11a swing check points for the invention. Said examples are illustrated and labeled as v1, v2, v3, v4 and v5. as to the variable quantity, size and shape options for negative spaces which may, but are not limited, to be provisioned within the flexible control arm 4 body to enable possible door 11a swing check points. Also pictured are provisioned through-holes 4b which may be used as mounting points for connecting fasteners to required or optional components as a part of the invention and its particular application requirements. All of the negative spaces illustrated may vary in size in relation to the application and the components being provisioned for various applications of the invention.

(28) Illustrated in drawing v1 are three negative check point location spaces 4b on the flexible control arm 4. These have a primarily rectangular form. You will also see four through-holes 4b for mechanical attachment.

(29) In drawing v2 we see the flexible control arm 4 provisioned with four ovoid teardrop shaped negative areas 4c check point locations. You will also see four through-holes 4b for mechanical attachment.

(30) Illustration v3 shows another variation with four spherical negative areas 4a check point locations. You will also see four through-holes 4b for mechanical attachment.

(31) Drawing v4 shows three spherical negative spaces 4a check point locations. The number and size of negative spaces is variable and may be utilized in a manner that is befitting the application. You will also see four through-holes 4b for mechanical attachment.

(32) In drawing v5 there are only two through-holes 4b on the flexible control arm 4 to illustrate that in some applications there is variability in the number (and size) of potential fasteners to be used in the invention, dependent on the needs of the particular application. In this instance, there is no requirement for the stop-block 15 assembly as seen in FIG. 9. There are three spherical negative spaces 4a check point locations on the flexible control arm 4.

(33) FIG. 9 Is an isometric view of the invention in an unmounted state. It should be noted that in this variation, an optional stop-block 15 is shown. This optional element is useful when the vehicle lacks an existing and/or installed door limiting strap 14a as seen in FIG. 7. The stop block assembly 15 features a through-slot 15a to accept entry of the flexible control arm 4. The stop-block 15 also features tool-free fasteners 16 of any design. In practical application, the flexible control arm 4 passes through receiver cover(s) 2 by way of provisioned through areas 2a, the receiver 1 in a linear manner by way of area 1a, and its attached and finally into the body of the stop-block's provisioned through-slot 15a where said component may be provisioned with through-holes 15b which may be brought into alignment with the two through-holes 4b on the flexible control arm 4. The tool-free fasteners 16 may be of any practical and applicable nature may then be inserted into and through the provisioned through-holes 15b located on the stop-block 15 as well as the through-holes 4b located on the flexible control arm 4 thus fixedly retaining the stop-block 15 in a pre-determined area upon the flexible control arm 4.