DE202008013129U1 - An air guide - Google Patents

Abstract

An air guide assembly to be mounted on an air outlet (12) of an electronic device and comprising
a plurality of ribs (13) rotatably mounted in the air outlet; and
a shape memory element (15) having one end to be attached to the electronic device and the other end connected to one of the ribs so as to pull on the ribs so as to pivot together when deformed by heating.

Description

The The invention relates to an air guide arrangement for use at the air outlet an electronic device.

electronic Devices generate heat during operation. To the normal operation of an electronic device is therefore a good heat dissipation design of importance. For example In a notebook computer, in general, the host part is a fan arranged with heat sink, the air from an air inlet at the top or bottom of the host unit and draws in heated air an air outlet, which is usually located on a side edge, blows out. The air is made by heat exchange with a heat source (for example, the CPU) of the notebook computer.

Around To prevent foreign substances from entering through the air inlet or outlet arrive, several ribs are arranged on these, in general orthogonal to the surface of the main body, and accordingly, air flows from the air outlet orthogonal to the surface of the main body. If the air outlet is located at the side edge of the notebook computer and the user's hand is on the same page, for example a mouse to use, the air is blown directly on the hand, which is perceived as unpleasant.

Around To solve the above problem, the air outlet at the Rear of a notebook computer can be arranged. however is in most cases, due to limited space, arranged the air outlet on the side edge of a notebook computer.

As an alternative, adjustable ribs have been proposed by notebook computer manufacturers. Also is in the U.S. Patent No. 6,229,701 proposed a portable computer with a heat dissipation device, wherein the heat dissipating fins pivotally arranged in a ventilation hole between an overlapping position for closing the hole and an open position are adjustable at an angle. However, the adjustable Wärmeabführlamellen according to this patent are very complicated.

Of the Invention is based on the object, an air guide arrangement for to create the air outlet of an electronic device which avoids it with a simple structure that exhaust air on the hand a user is blown.

These Task is through the Luftleitanordnungen according to the appended independent claims 1 and 3 solved.

The Air guide assembly according to the invention has a plurality of ribs, an actuator and an element with shape memory. The ribs are rotatable in the air outlet appropriate. The actuator is with each of the ribs connected to turn them synchronously. An end of the element with Shape memory is attached to the electronic device, while the other end with the actuator or directly with one of the ribs (the outermost Rib) is connected, so that it at thermal deformation on pull the ribs that they pivot together. If that is Element with shape memory is at normal temperature, The ribs are at a normal angle while then, if it is due to in the electronic device deformed heat, it pulls on the ribs, that they pan. Furthermore, the actuator drives each Rib so that they pivot together at a working angle, whereby the Luftausblasrichtung changed from the air outlet becomes.

If in the air guide assembly according to the invention an electronic device generates heat during operation, the element is heated with shape memory, and it stretches to pull at the ribs so that they touch one Swivel working angle. Therefore, the ribs can the Air blowing direction according to a temperature effect of the electronic Change device, causing this air deflector an optimal design for an electronic device forms.

The Invention will now be illustrated by figures Embodiments explained in more detail.

The 1 Fig. 12 is a perspective view showing an air guiding structure according to a first embodiment of the invention applied to a notebook computer;

2A and 2 B FIG. 15 are perspective views for illustrating the operation of FIG 1 contained air guide assembly;

3A and 3B are top views that the 2A respectively. 2 B correspond;

4 Fig. 10 is a perspective view showing an air guiding structure according to a second embodiment of the invention;

5A and 5B Fig. 15 is perspective views showing an air guiding structure according to a third embodiment of the invention;

6 Fig. 15 is a perspective view showing an air guiding structure according to a fourth embodiment of the invention;

7A and 7B Fig. 15 are perspective views for illustrating the use of an air guiding structure according to a fifth embodiment of the invention;

8th Fig. 11 is another perspective view illustrating the use of an air guide assembly according to a fifth embodiment of the invention;

9 Fig. 13 is a perspective view illustrating the use of an air guide assembly according to a sixth embodiment of the invention; and

10A and 10B Fig. 15 are perspective views for illustrating the use of an air guiding structure according to a seventh embodiment of the invention.

The Air guide assembly according to the invention is in Applicable to an electronic device that generates heat during operation generated, such as a desktop computer, a server or a Notebook computer. In the embodiments described below is assumed for the sake of illustration of a notebook computer.

The Indian 1 illustrated notebook computer has a host part 10 , inside which a fan 11 is arranged with heat sink. An air outlet 12 on one side edge is according to this heat sink ventilator 11 arranged.

According to the 2A and 2 B has the air guide assembly according to the first embodiment of the invention via a plurality of ribs 13 , an actuator 14 and an element 15 with shape memory. Each of the ribs 13 is plate-shaped, and above and below is each a rotation axis 131 arranged. At the top and bottom of the inner wall of the air outlet 12 are each several pin holes 121 arranged, in each of which one of the axes of rotation is inserted, whereby the ribs 13 in the air outlet 12 can rotate to change their angle. Also, on the long side of each rib 13 a connecting section 132 arranged. The actuator 14 is a rod-shaped rod on which several sleeves 141 are arranged, one of which is one of the ribs 13 equivalent. The connecting section 132 every rib 13 pivoted in the appropriate sleeve 141 so the ribs 13 connected in series and can rotate together when passing through the actuator 14 be driven to change the angle.

The element 15 with shape memory is present as a spiral or with other possible shapes, for example, irregularly linear, rod-shaped or plate-shaped. In the first embodiment, the shape memory element is exemplified as a spiral. One end thereof is at a side edge of the inner wall of the air outlet 12 (on the electronic device, ie on the host part 12 the notebook computer), and the other end is with one of the ribs 13 (in the figure of the outermost rib 13 ) connected. The element 15 with shape memory can, regardless of whether it is directly with one of the ribs 13 is connected or with the actuator 14 connected, evenly on all ribs 13 pull so that they pivot together. It also allows the connection between the element 15 with shape memory and ribs 13 that on all ribs 13 pulls evenly so that they pivot together when deformed due to supplied heat. Thereby, both, just mentioned embodiments are applicable to the invention, wherein, as an example, a shape memory element is used, which directly with one of the ribs 13 connected is.

The element 15 For example, shape memory is Ni-Ti, Cu-Zn-Al, or Cu-Ni-Al shape memory alloy, and it is deformable depending on the temperature. At normal temperature the element shows 15 with shape memory, an extended and deformed state, whereas at higher temperature, it exhibits a contracted original state. On the deformation of the element 15 with shape memory, after getting the ribs 13 at the normal temperature (for example, the heat sink ventilator 11 not in operation) at a normal angle, so pulled away that they pivot as the element 15 with shape memory contracts when heated (for example, the heat sink ventilator 11 in operation). This drives the actuator 14 Ribs 13 so that they pivot together to a working angle.

Also from the 3A and 3B it can be seen that in the described Luftleitanordnung the ribs 13 rotatable in the air outlet 12 are attached. The actuator 14 is with each of the ribs 13 connected. An end of the element 15 with shape memory is with a side edge of the air outlet 12 connected while the other end with the outermost rib 13 connected is. The element 15 with shape memory is at normal temperature (ie, the notebook computer is not in operation) in the stretched and deformed state, and the ribs 13 are at a normal angle orthogonal to the air outlet 12 as it is from the 3A is clearly recognizable. When the operation of the notebook computer starts, the heat sink fan pulls 11 from the outside cold air, and this leads to a heat source (not shown) of No tebookcomputers heat exchange, whereupon the heat sink ventilator 11 the generated warm air blows out through the air outlet. The element in continuous contact with the warm air 15 with shape memory is heated. When its temperature reaches a transition temperature, it contracts to its original contracted state, thus causing it to rip 13 pull that swivel. Furthermore, the actuator drives 14 Ribs 13 so that they pivot together to a working angle, as it is from the 3B is recognizable.

When a notebook computer has just been put into operation, the temperature of the shape memory element has not yet reached the transition temperature, and warm air is passing through the fins 13 through from the air outlet 12 blown out on the side edge of the notebook computer. As the temperature of the warm air continues to increase with continuous operation of the notebook computer and eventually reaches the transition temperature, thereby also causing the shape memory element to reach the same, all ribs pivot 13 on the working angle. The working angle is an angle oblique to the rear end of the shape memory element, which causes the warm air through the ribs 13 at the air outlet 12 is blown out at an oblique angle to the rear end of the notebook computer. Accordingly, the warm air is not directly blown to a user's hand when operating a mouse on the side of the air outlet, for example, whereby the user does not experience an uncomfortable feeling.

According to the described 2A . 2 B such as 3A and 3B the angle of rotation of each of the ribs varies 13 depending on different positions of the axis of rotation 131 every rib. The outermost rib 13 shows a center line L, which corresponds approximately to its center, and so the long side of the same is divided into two parts. It stands, at the same deformation volume, the angle of the ribs 13 after going through the item 15 pivoted away with shape memory, in inverse proportion to the distance from the pin hole 121 and the axis of rotation 131 to the element 15 with shape memory. That is, that if the axis of rotation 131 is closer to the point where the element 15 with shape memory with a rib 13 connected, this element 15 with shape memory at the same deformation volume so at the rib 13 can pull that this twists around a larger angle. In the first embodiment, the distance from the location where the element corresponds 15 with shape memory with the rib 13 is connected to the axis of rotation 131 about the distance from the point where the element 15 with shape memory with the rib 13 is connected to the center line L, ie, the axis of rotation 131 is arranged on the center line L.

When in the 4 illustrated air guide assembly according to a second embodiment of the invention is between a heat dissipation element or a heat sink (not shown, but it is, for example, a heat pipe, a Wärmeabführplatte or a heat dissipation rib set) of the notebook computer and the element 15 with shape memory, a heat conducting element 16 arranged. In the first embodiment of the invention, the heat sink fan blows 11 the warm air to the element 15 with shape memory, while in the second embodiment, the heat generated by the heat dissipation element or the heat sink directly to the element 15 is passed with shape memory, so that this reflects the current operating state of the notebook computer and in real time on the ribs 13 pulls to adjust this to the working angle.

In the in the 5A and 5B illustrated air guide assembly according to a third embodiment of the invention is on the inner wall of the other side of the air outlet 12 , opposite to the element 15 with shape memory, a reset element 17 arranged, one end of which is at a side edge of the inner wall of the air outlet 12 is attached while the other end with the corresponding outermost rib 13 ie with the outermost rib 13 on the side opposite to the element 15 with shape memory, is connected. The reset element 17 here is a tension spring, but is not limited thereto, and it is normally in a compressed state, the stretched and deformed state of the element 15 corresponds with shape memory. When the element 15 is with shape memory in the contracted original state, is the return element 17 stretched, making it the element 15 with shape memory can help to regain the contracted original state when the operation of the notebook computer stops, whereby each of the ribs 13 can reach its normal angle again. In this case, when the operation of the notebook computer stops, the temperature of the element falls 15 with shape memory gradually to below the transition temperature. The reset element pulls 17 at the normal temperature at the ribs 13 , causing the element 15 with shape memory resumes the stretched and deformed state, and further pulls the actuator 14 each of the ribs 13 back to the normal angle.

In the first, second and third embodiments, the element is 15 with shape memory on a side edge of the air outlet 12 arranged, and it deforms in a direction orthogonal to this. However, in the case of 6 illustrated air guide assembly according to a fourth embodiment of the invention, the element 15 with shape memory according to the interior configuration of the notebook computer so arranged in this that it is in a direction parallel to the air outlet 12 can deform. Therefore, one end of the element 15 attached with shape memory directly to a heat dissipation element or a heat sink (not shown), and the other end is on a pull rod 133 the outermost rib 13 attached to pull on it, causing it to rotate.

The in the 7A . 7B and 8th illustrated air guide assembly according to a fifth embodiment of the invention differs only slightly from the first embodiment, therefore, only the difference will be described below. In the fifth embodiment, the rotation axis 131 and the mortise hole 121 every rib 13 closer to the element 15 with shape memory as arranged in the first embodiment, ie, the distance from the point at which the element 15 with shape memory with the rib 13 is connected, to the axis of rotation 131 is smaller than the distance from the point where the element is 15 with shape memory with the rib 13 connected to the midline L. This allows the element 15 with shape memory at the same deformation volume so on the ribs 13 pull that they twist at a greater angle than in the first embodiment. It can also be the position of the axis of rotation 131 remain unchanged, and instead becomes the element 15 with shape memory to the inside of the air outlet 12 offset. Even then, the element can 15 with shape memory at the same deformation volume so on the ribs 13 pull that they twist around a larger angle. In addition, as it is in the 8th is shown, the axis of rotation 131 and the mortise hole 121 each of the ribs 13 further from the element 15 remotely located with shape memory, ie, the distance from the point where the element 15 with shape memory with the rib 13 connected to the center line L, which also falls within the scope of the invention.

The air guide arrangement according to the in the 9 illustrated sixth embodiment of the invention is similar to that of the first embodiment, so only the difference will be described. In the sixth embodiment, one end of the element 15 with shape memory with a side edge of the inner wall of the air outlet 12 connected while the other end directly to the actuator 14 connected is. Thus, in contrast to the first embodiment, the element pulls 15 with shape memory in this embodiment directly on the actuator 14 , making this all ribs 13 so drives them to pan together.

The air guide arrangement according to the in the 10A and 10B The illustrated seventh embodiment of the invention is similar to those of the first embodiment, therefore, only the difference will be described below. In this seventh embodiment, the element consists 15 with shape memory of two rod-shaped metal materials of different thermal expansion coefficients. An end of the element 15 with shape memory is with a side edge of the inner wall of the air outlet 12 connected while the other end is movable with the rib 13 connected is. The element 15 with shape memory is with a pen 151 in a management staff 134 the rib 13 introduced. If the element 15 is heated with shape memory, the two metal materials expand due to their different thermal expansion coefficients to varying degrees, so that the element 15 with shape memory when heated to the end of the metal material with a lower coefficient of thermal expansion, thus bending at the ribs 13 to pull that swiveling. Furthermore, the actuator drives 14 Ribs 13 so that they pivot together on the working angle. Also, by this embodiment, the heat blowing direction can be changed depending on the temperature, and when the normal temperature is reached again, the element returns 15 with shape memory automatically returns to its original state, around the ribs 13 to pull back to the normal angle.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 6229701 [0005]

Claims (11)

Air baffle arranged at an air outlet ( 12 ) of an electronic device and comprising: a plurality of ribs ( 13 ) which are rotatably mounted in the air outlet; and an element ( 15 shape memory, one end of which is to be fixed to the electronic device and the other end connected to one of the ribs so as to pull on the ribs so as to pivot together when deformed by heating. An air guide arrangement according to claim 1, characterized by one with the ribs ( 13 ) associated actuator ( 14 ) to drive the ribs so that they pivot together. Air baffle arranged at an air outlet ( 12 ) of an electronic device and comprising: a plurality of ribs ( 13 ) which are rotatably mounted in the air outlet; an actuating element connected to the ribs ( 14 ) and an element ( 15 shape memory, one end of which is attached to the electronic device and the other end is connected to the actuator so that it pulls on the ribs so that they pivot together when deformed by heating. Air baffle arrangement according to one of the preceding claims, characterized in that at each rib ( 13 ) a connecting portion is present on the actuating element ( 14 ) are arranged a plurality of sleeves, each of which corresponds to one of the connecting portions, and the connecting portions of the ribs are each pivotally connected to the sleeves, so that the ribs can rotate together. Air guide arrangement according to one of the preceding claims, characterized in that a return element is present, one end of which at a side edge of the inner wall of the air outlet ( 12 ), while the other end with the outermost rib ( 13 ) on the side opposite to the element ( 15 ) is connected to shape memory, wherein the shape memory element at normal temperature has a stretched and deformed state, while having a contracted initial state when heated, so that the ribs are initially at a normal angle and then pivoted to a working angle, and wherein the return element returns the shape memory element to the stretched and deformed state at the normal temperature. An air guide arrangement according to claim 5, characterized in that each of the ribs ( 13 ) has a center line (L) and the distance from the point at which the element ( 15 ) is connected with the shape memory with the rib, to the axis of rotation ( 131 ), smaller than the distance from the point where the shape memory element is connected to the rib is to the center line. An air guide arrangement according to claim 5, characterized in that each of the ribs ( 13 ) has a center line (L) and the distance from the point at which the element ( 15 ) is connected with the shape memory with the rib, to the axis of rotation ( 131 ), the distance from the point where the shape memory element is connected to the rib corresponds to the center line. An air guide arrangement according to claim 5, characterized in that each rib ( 13 ) has a center line (L) and the. Distance from the point where the element ( 15 ) with shape memory connected to the rib, to the axis of rotation ( 131 ), which is greater than the distance from the point where the shape memory element is connected to the rib, to the center line. Air guide arrangement according to one of the preceding claims, characterized in that on the top and the bottom of the inner wall of the air outlet ( 12 ) a plurality of pin holes are arranged on the top and bottom of each rib ( 13 ) each have a rotation axis ( 131 ) is arranged, and the ribs are pivotable in that the axes of rotation are inserted into the pin holes. Air guide arrangement according to one of the preceding claims, characterized in that a heat-conducting element is present, whose one end is connected to the element ( 15 ) is connected to shape memory and the other end is connected to a heat sink of the electronic device. Air guide arrangement according to one of the preceding claims, characterized in that one of the ribs ( 13 ) has a pull rod and one end of the element ( 15 ) is connected thereto with shape memory, while the other end is fixed to a heat dissipation element of the electronic device.