HUT62726A - Battery carrier construction for electronic apparatuses, for instance to radiotelephones - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a battery support device for portable electronic devices, radiotelephones, and more particularly to a battery housing having an integral part thereof with a movable sliding trough structure having a notch on adjacent guide rails.

Miniature electronic devices are often portable and, as such, require a portable power source such as a battery. The power supply battery can advantageously be connected to the housing of the miniature electronic device and may be electrically contacted therewith using a conventional contact. To facilitate battery replacement, various structures have been designed to allow the user to disconnect the empty battery and replace it with a freshly charged battery. A solution has been desirable whereby the demountable battery is securely attached to the miniature electronic device by means of a sliding trough and a locking device. However, as the devices become smaller, it becomes increasingly difficult to choose the dimensions that affect the quality of the connection between the battery and the electronic device. Such critical connection features include sliding trough, latch and battery contacts.

Generally, battery housings are structures that include a base and a cover, and are secured to one another and occupy the electrochemical cells contained within the structure. The sliding trough type solution is often integrated with the structure of the rack housing and the trough sliding structure is a combination of the rack base and the cover. Changes in the assembly process of the housing base and cover also change the size of the sliding troughs from time to time. The change involves the relative size csúszóvályúk arranged latch of the battery casing and battery contacts ^- a change in position relative to the sliders. As a result, the battery may not fit properly or function properly when connected to an electronic device. Consequently, it would be advantageous to fabricate all critical connector members so that they form part of the base of the housing and thus maintain their relative dimensions.

The arrangement or manufacture of all connecting elements in the base of the housing makes it difficult to form guide rails for the sliding troughs. The sliding trough usually has three inner surfaces which form a U-shape. The guide rails are generally elongated protrusions spaced apart on one of the two inner surfaces of the sliding trough parallel to one another. The bottom surface of the sliding trough is generally perpendicular to the two lateral surfaces. The guide rails are parallel to the bottom surface. Using conventional injection molding techniques, the slider troughs are locked into the latch and battery contact sockets at the base of the casing, which assumes that the workpiece has to be lifted or ejected straight out of the tool cavity. However, the guide rails in the sliding troughs are perpendicular to the direction of ejection from the tool cavity.

One possible solution could be injection molding. Using this method, the sides of the slide troughs, along with the guide rails on them, are first sputtered, then placed in a second mold, which forms the remaining two sides of the slide channel and the entire injection molded base of the battery holder. The problem with this solution is that complete injection molding in two steps is labor and time consuming.

Alternatively, joint injection molding may be an option. In this process, the sides of the slides, including the guide rails, are injection molded in a first step. Then, one part of the tool is removed and replaced with another part, in which the remaining parts of the sliding trough and the entire base of the housing body are formed. In the second injection molding, the entire base of the battery housing is formed. The difficulty with this solution is that they cannot be automated together *. injection molding tools, which are capable of executing the first step in a straight extraction direction and the second step in a direction perpendicular to the first step. It would be very costly to develop a special injection molding process for the base of the cellular housing.

Consequently, there would be a great need for a battery support base having an integral part of it with a limited displacement sliding trough structure with guide rails which is simply harmful, maintains the dimensions of the critical connector and does not depend on the connection of the housing cover. The object of the invention is to meet this need.

In accordance with the present invention, there is provided a battery holder structure for portable electronic devices, the battery holder device comprising at least one first and second battery housing parts comprising electrochemical cells. The first battery housing part has at least one connector surface by which the battery holder assembly is detachably connected to the portable electronic device. The battery support structure comprises at least one trough which is arranged on the connecting surface of the first housing part.

The at least one trough further comprises at least a first surface, at least one elongate on the first surface and a projection parallel to the engaging surface along the first surface, and at least one long notch such as an elongated protrusion, placed adjacent to its end.

The battery holder according to the invention will now be described, by way of example only, in the accompanying drawing. embodiment. In the drawing:

Figure 1 is a perspective view of a hand-held portable radiotelephone for use with the battery holder of the present invention; Fig. 2b Fig. 2b. Fig. 4A shows a rear view of the portable cellular telephone with the battery housing removed;

Figure 3 2a. The housing base of FIG view with integrated latch, electrical contacts and reducer  with movable guide rails, Figure 4 the housing shown in Figure 3 is sectioned detail view, Figure 5 2a. 3A is a sectional view of the base and cover of the housing shown in FIG.

Figure 1 shows a portable radiotelephone device for use in a cellular radiotelephone system. The battery holder of the present invention can be used for such a portable radiotelephone device, but also for other miniature electronic devices. The portable unit shown comprises two outer portions, a housing 102 and a folding tab 104, plus a detachable housing 105. Fig. 1 shows the fold-out tab 104 in the open position, which allows the handset user to listen to the listener 106 and talk into the microphone 107. For dialing, the buttons 110 are properly numbered from one to ten and have other markings used in telephones. The push buttons 110 may also be provided with function keys such as, for example, transmit, end, on and off numbers, and other associated keys.

Since the portable cellular telephone of FIG. 1 is truly portable, it requires some power source to provide electrical power to the cellular telephone. This electrical energy is provided by 105 batteries, which are generally in the form of a rechargeable electrochemical cell or cells. It is expected that the user will be able to charge the battery even when it is connected to the radio, but it must be charged separately.

2a. FIG. 3B illustrates a configuration of a detachable battery 105 when disconnected from the portable radio shown in FIG. In a preferred embodiment of the present invention, the housing is made up of two halves, the base 300 shown in FIG. FIGS. 1A and 4b comprise cover 202, which are permanently attached to one another. Non-conventional and conventional electrochemical batteries can be placed between the two plastic housing parts, which can be attached to one another and form a combined battery group in one housing.

The latch 201 is integral with the base 300 of the housing body as a one-piece injection molded structure. This closure is molded together with the inside of the plastic housing. To detach the battery 105 from the cellular telephone 102, the latch 201 is shown in FIG. 2a. 2, the torsion bar (not shown) is rotated and the tongue (not shown) is lifted out of the slot 212 of the portable radio 102. (The portable radiotelephone 102 with the battery removed in the rear view is shown in Figure 2b.) This operation releases the battery from its fixed position and allows the body 105 to be removed from the portable radiotelephone 102. On the mating surface of the portable radiotelephone 102, a slot or a notch 212 is formed such that it is engaged and engages with the tongue of the latch structure 201 when the housing body 105 is fully engaged. The housing 105 is then locked in place. A guide rail 213-218 extends from the surface of the housing of the portable radiotelephone device 102 and opposes similar guide rails of the housing 105. The guide rails of the housing 105 are below the guide rails 213-218 of the housing 102 of the portable radiotelephone when the housing 105 is in the operating and locked position. Of course, an operating position is understood to mean when the electrical contacts 225 are in contact with the contacts 325 on the housing body 105 but not visible.

2a. In FIGS. 2 to 4, lateral slots 233 and 235 are formed on opposite sides of the housing body structure 105, such that the battery itself, and the battery and the portable radiotelephone together, can be slid into a common battery charging unit that properly positions and guides the charging chamber contacts.

The base surface 300 of the housing body 105 is shown in front view 302 in FIG. FIG. The base 300 essentially includes a latch and structure 201, slides 507, contacts 325 formed as a base for the battery, and recesses 313-316. The structure of the latch 201 is shown in detail in Figure 3, which illustrates how the tongue 301 rotates around the torsion bar 303 when a portion of the button 305 is pressed by a user to remove the battery. The outward pressure in the plane of Figure 3 (in the region defined by the notch 227 in the housing of the portable radiotelephone 102) rotates the torsion bar 303 and moves the tongue 301 in the plane of the panel of Figure 3. This movement lifts the tongue 301 out of the seat 212 (shown in Figure 2b) and thereby unlocks the housing 105 and allows the user to slide the battery along guide rails 307-312. The truncated guide rails 307-312 are disposed on opposing parallel surfaces of each channel and have slots between them that allow the body 105 to be securely anchored to the portable radiotelephone housing 102 along the entire length of the body 105 while allowing relatively short travel paths 105. for the battery housing, before the battery housing can be unlocked and removed from the handset 102 of the portable radiotelephone. When the guide rails 307-312 are completely disconnected from the handset 102 of the portable cellular telephone, the electrical contacts 325 of the battery are disconnected from the input electrical contacts 25 of the portable cellular telephone 102. If the guide rails 307-312 are displaced along the opposite guide rails 213-218 on the housing 102 of the portable radiotelephone, the housing 105 may be freely lifted from the housing 102.

In the preferred embodiment, the guide rails 307-312 are projectile (see Figure 4), but in other embodiments may resemble other shapes to perform the same function. The guide rails 307-312 must be oblong, parallel to the connecting surface 302 of the base of the battery 105, and the mating surfaces must lie parallel to the guide rails 213-218 on the housing 102 of the portable radiotelephone. .

One feature of the preferred embodiment of the invention is that there is a notch between two adjacent guide rails. The base 300 of the housing 105 includes four such incisions 313-316. In the preferred embodiment, these notches form a small tapered step on the surface 3 of the slide trough 507. The notches may not be limited to a narrower staircase, a narrowing slope, or any other shape that is lower than the plane on which the protrusions are located. These cuts have two purposes. The first object is to enable the rails 307-312 to be formed as an integral part of the base 300. In manufacturing, a single injection is applied with a straight workpiece ejection. This manufacturing operation is cheap and the injection molding time is short. Injection molding of the guide rails 307-312 as an integral part of the base 300 has the advantage that the critical connection dimensions of the base 300 of the body 105 and the housing 102 of the portable radiotelephone can be met. Importantly, the relative dimensions of the guide rails 307-312 between the latch structure 201 and the battery contacts 325 formed as the base of the battery can be maintained in order to ensure that the battery 105 fits properly and functions well with the handset 102 of the portable radiotelephone. Furthermore, adherence to the critical dimensions of the base 300 has the advantage that these critical dimensions are not affected by the connection or fastening of the cover 202 of the housing body 105.

The second purpose of the notches 313-316 formed on the basis of the housing body 300 is to enable the housing 105 to be easily connected to the housing 102 of the portable radiotelephone. The notches 313-316 increase the width of the sliding trough in the gap between the guide rails of the base 300. This increased width allows the guide rails 307-312 in the housing 102 of the portable radiotelephone to fit into the gap with less friction. The guide rails 307-312 on the housing 102 are bullet-shaped at their front ends to slide out of the notched step of the sliding trough of the housing body. This makes it easier for the user of the portable radiotelephone to connect a properly fitting battery.

Figure 4 is a sectional and perspective view showing a detail of the base 300 of the housing body 105. This figure shows in more detail the construction of one of the notches 314 between two guide rails 308 and 309. The notch 314 is at least as long as the length of the guide rail 309. The stepping depth is typically 0.07 mm on each of the three surfaces of the slide trough 507. The flat end of the guide rail 308 is directly adjacent to the notch 314. As mentioned above, the notch 314 allows the guide rails 307-312 to be injection molded as an integral part of the base 300. Generally, these notches 313-316 open the portions between the guide rails 307-312 and allow the tool portion forming the guide rails 307-312 to slide into the slot. The direction of this sliding is from the guide rail 308 to the guide rail 309. Due to the direction of sliding, the guide rail 308 must be connected to the notch 314 so that the sliding tool may leave the guide rail 308. If the tool is detached from the guide rails, the base of the battery housing will be lifted out or thrown out of the tool cavity. This sliding and lifting step of the manufacturing operation is similar to removing the housing body 105 from the housing 102 of the portable radiotelephone.

The integral guide rails are made by a four step injection molding process after the thermoplastic material has been injected into the tool and the die has cooled. In a preferred embodiment, the housing parts are injection molded from polycarbonate or the like thermoplastic material. In the first step, the part of the tool which creates the notch is removed. In the second step, the guide rail forming part is slid about 22 mm long. This is a slip! operation moves the tool portion forming the guide rails 308 and 309 into the slot. The notch 314 ensures that the sliding action of the sliding tool does not fix or hold a portion of the base 300 which produces a portion of the sliding channel in the slit. Typically, the sliding tool may cure as the plastic shrinks before the tool slides into the gap. Similarly, the sliding tool can grip the line created by the tool adjacent to the sliding tool while the tool slides. Notching solves both problems. Once the guide rail tool has slipped into the slot, the third step opens the tool and in the fourth step the base 300 is ejected from the tool cavity.

Figure 5 shows a cross-sectional detail of the base 300 and the lid 202 of the battery holder 105 before they are joined together. In a preferred embodiment, the base 300 and the lid 202 are bonded to each other by ultrasonic welding. During this operation, the pointed cam 501 formed on the base 300 is inserted into the groove 503 of the cover 202. After insertion, energy is applied to the base 300 by means of an ultrasound generator, which then fuses the pointed cam 501 to the groove 503. This operation provides a secure and durable bond between the base 300 and the cover 202. A feature of the preferred embodiment of the present invention is that the method of joining the base 300 and the lid 202 does not affect the shape, fit or operation of the guide rails 309 in the slide trough 507. For the user of a portable radiotelephone, this property means that the shape of the battery always matches the guide rails in the sliding trough. The latch assembly and battery connectors are properly fitted and cooperate well with the handset 102 housing.

Thus, the integral housing has a sliding trough mechanism for integrally limited displacement, resulting in a short travel path between the connected and unlocked position of the housing together with the housing of the portable radiotelephone device shown. The base can simply be molded with one injection and pulled by one puller in the molding process. Critical connector sizes on the base can be held properly regardless of how the cover connects to the base.

Claims (10)

A battery holder for a portable electronic device having a mating first and second housing portions comprising an electrochemical cell therebetween, and the first housing portion having at least one connector surface for detachably connecting the battery holder to the portable electronic device. at least one trough is formed on the connecting surface of the first part of the battery support structure, which trough (a) at least one front surface; b) at least one elongated protrusion on its first surface parallel to the joint surface on the first surface; and c) at least one notch that is at least as long as the oblong protrusion and is located on at least a portion of the first surface adjacent to at least one end of the oblong protrusion. The battery holder according to claim 1, characterized in that the first housing comprises a locking device. The battery holder according to claim 1, characterized in that the first housing is provided with at least one mating contact for the battery. The battery support structure according to claim 1, characterized in that the at least one notch is formed as a recessed stair. The battery carrier structure of claim 1, wherein: tel-Λ Λ »** ** ** ** ** **» »» »» »» Characterized in that it comprises a second trough parallel to the first trough, which is formed in the connection surface of the first housing part. The battery support structure of claim 5, wherein the second channel is: (a) at least one first surface; (b) at least one elongated protrusion on the first surface extending along the first surface parallel to the connecting surface, and c) at least one notch that is at least as long as the oblong protrusion and is located on at least a portion of the first surface adjacent to at least one end of the oblong protrusion. A battery holder for a portable electronic device having a mating first and second housing portions comprising an electrochemical cell therebetween, and the first housing portion having at least one connector surface whereby the battery holder is detachably connected to the portable electronic device. battery holder structure: at least one trough is formed on the connecting surface of the first part thereof (a) at least one front surface; b) at least one elongated protrusion on its first surface parallel to the joint surface on the first surface; and (c) has at least one notch which is at least as long as the elongated protrusion and the first surface; ♦ · · »» »» »» ». - located on at least a portion of the 16 adjacent at least one end of the elongate protrusion; and further with a locking device; and having at least one mating contact for the battery. The battery support device according to claim 7, characterized in that it has a second trough, which is substantially parallel to the first channel and disposed on the connection surface of the first housing part. 9. The battery support structure of claim 8, wherein the second channel (a) at least one front surface; b) at least one elongated protrusion on its first surface parallel to the joint surface on the first surface; and c) having at least one notch which is at least as long as the oblong protrusion and is located on at least a portion of the first surface adjacent to at least one end of the oblong protrusion. A battery holder for a portable radiotelephone device having a mating first and second housing portions comprising an electrochemical cell therebetween, and the first housing portion having at least one connector surface for detachably connecting the battery holder device to the portable electronic device, and having a second trough, which are substantially parallel to each other and formed in the connecting surface of the first housing part, and the first and second troughs (a) at least one front surface; b) at least one elongate protrusion on its first surface parallel to the joint surface on the first surface; and c) at least one notch which is at least as long as the oblong protrusion and is located on at least a portion of the first surface adjacent to at least one end of the oblong protrusion; and further with a locking device; and having at least one mating contact for the battery.