FI126977B - PUSH BUTTON - Google Patents

Description

Button spindle Technical field

The invention relates to a button spindle. The button spindle is used on the doors to connect the button to the door lock.

State of the art

The door lock is connected by a spindle to a button used to open and close the door. The button can also be used to pull the lock bolt into the lock body. The button spindle is normally made of metal. In some applications, such as sliding doors, it is also known to use a plastic spindle as disclosed in EP 1398435.

At the exterior doors, the spindle conducts heat from the inside. Especially in winter, the heat flow through the mandrel can be considerable. This is because the outside door spindles are metal. The metals used in the spindles are good heat conductors.

Brief Description of the Invention

The object of the invention is to reduce the heat flow through the button spindle. The purpose is achieved as set forth in the independent claim. The dependent claims illustrate various embodiments of the invention.

The push-button spindle according to the invention is a composite material comprising reinforcing fibers and a resin or polymer as a binder. The fibers are end to end spindle and the fibers are 55 to 70 percent by volume of the composite spindle material. The composite material forms a shell structure around a longitudinal central axis of the mandrel, and the shell structure consists of a plurality of superimposed layers. The fibers of the layers are transverse to the longitudinal center axis of the spindle such that at least the outermost layer fibers are substantially at an angle of 40-50 degrees with respect to the longitudinal center axis of the spindle; or certain directness requirements.

List of figures

The invention will now be described in more detail with reference to the accompanying drawings in which:

Figure 1 illustrates an example of an inventive button spindle mounted on a door,

Figure 2 illustrates an example of a button spindle according to the invention,

Figure 3 illustrates an exemplary cross-section of a button spindle according to the invention,

Figure 4 illustrates another example of a cross-section of a spindle according to the invention, and

Figure 5 illustrates the straightness requirement of the fibers.

Description of the Invention

Figure 1 illustrates an example of an inventive button spindle 1 mounted on an exterior door 14. Button 10 is the inside of the button, and the button 11 is outside of the button. Inside button has a recess 10A for spindles. The external button has a corresponding recess 11 A. The door 14 has a mounting hole 15 is 1, for the spindle. In addition, the door has a lock 16, which is depicted in Figure 1 by a broken line. The spindle can be used to rotate either button to pull the lock catch inside the door and to open or close the door.

From Figures 1, it can be seen that the spindle 1 conducts heat from inside the door to the outside of the door. Inside the button 10A and the outer side of the button 11A to enhance heat transfer, because the buttons are made of metal, and they increase the heat transfer surface area. Because the spindle 1 according to the invention is a composite material, it has significantly less heat conductivity than the metal spindle.

Composite materials are known per se, but have not been successfully used prior to button spindles since the spindle must withstand relatively high torque loads. The spindle shall withstand a torque of at least 40 Nm. In addition, the wear resistance must be good for the spindle to last for decades.

Thus, the use of composite material as such does not yet produce a mandrel that is realistically usable and durable. This applies especially to the spindles of the exterior doors. Requirements and service life for interior doors may be lower.

Figure 2 shows an example of a spindle 1 according to the invention, and Figure 3 shows an example of a cross section of a spindle according to the invention. The push button spindle 1 according to the invention is a composite material 2 comprising fibers 3 as a reinforcement and a resin or polymer 4 as a binder. A polymer is a molecule in which several small molecules are linked together by chemical bonds. The polymers can be divided into synthetic and naturally occurring. Plastics are common synthetic polymers. For example, PPS or PP plastic can be used as a binder. The fibers are carbon fiber. Other materials can also be used as fibers such as kevlar, glass and natural fibers. For example, linen is made of natural fiber.

The fibers 3 are at the end of the spindle 1 and the fibers are 55 to 70% by volume of the composite material of the spindle. The composite material 2 forms a shell structure around a longitudinal central axis of the mandrel. Figure 2 illustrates the central axis on line A. The shell structure consists of a plurality of overlapping layers 5. There may be 8 to 12 overlapping layers.

The fibers of the layers are transverse to the longitudinal center axis of the spindle such that at least the outermost layer 5 fibers are substantially at an angle of 40-50 degrees with respect to the longitudinal center axis of the spindle and the fibers of the other layers are substantially at 30-60 degrees a certain directness requirement. As can be seen in Figure 2, in the angular areas B of the spindle sides, the angle of the fiber with respect to the central axis may be different from the angles containing the above areas. Also, the fiber moisture requirement may be different at angles than on the spindle composite layers.

Figure 3 illustrates how the bark layer consists of a plurality of overlapping layers 5. The spindle 1 of the embodiment of Figure 3 is hollow in the center in the longitudinal axis of the spindle. Figure 4 illustrates another embodiment in which the hollow space of the mandrel is filled with a poorly conductive material 17. The poorly conductive material may be, for example, polyurethane. In addition, Figure 4 shows a possible additional layer 18 on top of the outer composite material layer 5. The purpose of the additional layer is to increase wear resistance, if desired. The material of the additional layer is some suitable material, such as epoxy. The mandrel may further comprise more than one additional layer 18 on top of said outer composite material layer 5. As the spindle has additional layers, its thickness is also taken into account to fit the spindle to the buttons and lock body.

The above straightness requirement is that for a given length, anywhere on the fiber, the fiber location remains within a certain range. Figure 5 illustrates this purity requirement. The fiber 3 of Figure 5 fulfills the straightness requirement because it remains within the fiber length L within a given region AC anywhere along the fiber. The fiber 3 thus remains within a virtual cylinder 20 of a certain shape having a height L and a cross sectional area AC. The length L and the region AC can be defined as being dependent on the diameter of the fiber 3. For example, the length L may be the diameter of k *, where k is a factor such as 10. The area AC may, for example, be dependent on the diameter of the fiber such that the area AC is j * the diameter of j where j is a factor such as 4. becomes silicon / 4 * G * fiber diameter) 2. Since the diameter of the fiber is expressed in pm, so is the diameter of L and the area AC in pm. Since the mandrel is normally square in cross-section, the straightness requirement at the corners may be different from that of the sides of the square, i.e. the mandrel layers.

The methods described above provide a composite spindle that withstands the stress on the spindle of a button and also has a long life. The use of multiple layers forms a stronger structure than the use of a single thick structure. Also, the positioning of the fibers transversely to the longitudinal axis of the mandrel strengthens the structure. In addition, the transversely placed fibers extend the distance of heat transferred along the fibers, i.e., increase the heat resistance.

Furthermore, it is important that especially the outer composite material layer 5 (the furthest layer viewed from the longitudinal center axis of the mandrel) meets the straightness requirements as described above. If the straightness requirements are not met, the outer composite layer of spindle material comprises a weakening point or points, and the spindle may not withstand the stresses of use. The application of the straightness requirement to at least the outermost layer is due to the fact that the outermost composite material layer is subjected to the greatest stress.

The shell kernel structure is very strong and, moreover, when the middle region of the chicken is hollow or filled with heat-insulating material, the heat transfer resistance of the spindle is higher than that of a spindle made entirely of the same material. The thermal conductivity coefficient achieved by the invention is less than 0.5 W / Km. In most embodiments of the invention, the thickness of the shell layer is about 2 mm. That is, if there are 10 composite layers, the thickness of the individual composite layer in this case is about 0.2 mm. As already stated above, each composite layer comprises fibers spindle end to end.

In Figure 1, the fibers 3 are shown so that they all twist in the same direction in the layer. However, if fibrous socks are used in the manufacture of the spindle, in which the fibers are woven transversely to one another, then about half or half of the fibers rotate clockwise in the layer and respectively about half or half of the fibers anticlockwise. Here again, at least the fibers of the outermost layer 5 are at an angle of 40 to 50 degrees to the longitudinal center axis of the mandrel, and the fibers of the other layers are at 30 to 60 degrees to the longitudinal center axis of the mandrel. In the outer layer, the aim is to keep the fibers as close as possible to a 45 degree angle.

Button spindle size is normally 8 * 8 mm, but it can also be 10 * 10 mm for some special applications. Normal spindle lengths are 110 mm and 120 mm. This means that a relatively small area is subjected to relatively high stresses, such as torque of 40 Nm and surface pressures of more than 500 MPa near the spindle angles. The invention is able to withstand these heavy stresses with materials which, on the whole, carry much less heat than the metals used in the spindles, which has been achieved by the structural solutions described above.

In the light of the above examples, it is clear that many embodiments of the invention can be achieved. It is also possible that the composite mandrel can be made to withstand fire situations by also using a flame retardant in the binder. Thus, the invention can be implemented in many different embodiments within the scope of the independent claim.

Claims (6)

A button spindle (1) made of a composite material (2) with reinforcing fibers (3) and a resin or polymer (4) as a binder, characterized in that the fibers (3) are end to end of the spindle (1) and - 70% by volume of the composite spindle material, the composite material (2) forming a shell structure around a longitudinal center axis of the spindle, the shell structure consisting of a plurality of superimposed layers (5) transverse to the longitudinal center axis of the spindle the fibers being substantially at an angle of 40 to 50 degrees to the longitudinal center axis of the mandrel, and the fibers of the other layers being substantially at an angle of 30 to 60 degrees to the longitudinal center axis of the mandrel, and at least the outermost layers meeting certain or straightness requirements. Spindle according to claim 1, characterized in that the spindle (1) is hollow in the center in the direction of the longitudinal axis of the spindle. Spindle according to Claim 2, characterized in that the hollow space of the spindle is filled with a material with poor thermal conductivity. Spindle according to one of Claims 1 to 3, characterized in that the straightness requirement or straightness requirements are that, for a given length, anywhere on the fiber, the fiber location remains within a certain range. Spindle according to claim 4, characterized in that the number of layers is 8 to 12. Spindle according to one of Claims 1 to 4, characterized in that the spindle further comprises at least one layer on top of said outer layer of composite material. Krav