TWM519335U - Positioning structure and motherboard - Google Patents

Abstract

A positioning structure for positioning a CPU over a transmission area of a base of a connecter is provided. The CPU has a contact surface. The positioning structure includes a frame and at least two positioning components. The frame has an opening. The positioning components are movably disposed on the frame. The positioning components are suitable for carrying the CPU, so that the CPU may be positioned over the opening. Each of the positioning components has a first end portion away from the frame relatively. When the frame is placed onto the base and the CPU is supported on the positioning components, the opening surrounds the transmission area and the contact surface faces the transmission area. The first end portions are suitable for moving close to the frame so as to make the contact surface contact the transmission area after the CPU moves away from each of the positioning components.

Description

Positioning structure and motherboard

The novel creation relates to a positioning structure and a motherboard, and in particular to a positioning structure and a motherboard for positioning a central processing unit.

With the rapid development of electronic technology, electronic products have been filled around our lives, and the emergence of computers has affected our work and daily life. In order to improve the performance of the computer and meet the needs of users, the internal parts of the computer are constantly being updated. In the case of a central processing unit (CPU) used in a computer, in the process of continuously integrating the audio chip, the graphics chip, and the network chip into the motherboard, the central processing unit is mostly installed in a modular manner to the host. On the board, it means that the motherboard is equipped with a connector for central processor installation. After the central processor is mounted to the connector, the plurality of contacts on the central processor are respectively abutted with the plurality of terminals on the base of the connector to be electrically connected to each other.

Since the number of the aforementioned terminals can be several hundreds and is accommodated in a limited area on the base of the connector, the structure of the aforementioned terminal is fine and is easily deformed by an external force. By installing the central processor to the connector on the motherboard, Most of them are done by hand. In the process of installing the central processing unit to the connector on the main board by hand, if the operator's hand accidentally touches the aforementioned terminal, the terminal is easily deformed. Or alternatively, the central processor may be deformed by the impact of the central processor when the operator's hand slides down onto the seat. That is to say, when the aforementioned terminal is deformed due to improper force, the connector may lose the electrical connection to the central processing unit, and the motherboard to which it belongs may not continue to be used.

The novel creation provides a positioning structure that helps to improve the accuracy and stability of the installation of the central processor to the connector.

The novel creation provides a motherboard that helps improve the accuracy and stability of the central processor when installed.

The present invention proposes a positioning structure adapted to position the central processor above the conductive area of the body of the connector. The central processor has a contact surface. The positioning structure includes a frame and at least two positioning members. The frame has an opening. The positioning members are movably disposed on the frame. These locators are adapted to carry a central processor above the opening. Each of the positioning members has a first end and a second end. When the frame is placed on the base body, and the central processor is carried on the positioning members, the opening surrounds the conduction area, and the contact surface faces the conduction area, and the first end of each positioning member is adapted to move closer to the frame body. The contact surface of the central processing unit is abutted against the conductive area after the central processor is moved away from the respective positioning members.

In an embodiment of the present invention, the second ends of the positioning members are connected to each other. The positioning structure further includes a lever. The control rod is movably disposed on the frame. The lever has a pushing portion located inside the frame. The pushing portion is disposed corresponding to the second end of one of the positioning members. The lever is adapted to reciprocate between a first position and a second position. When the control rod is in the first position, and the central processor is carried on the positioning members, the pushing portion pushes against the second end portion of one of the two positioning members, so that the first end portion of each positioning member moves away from the frame body. A first distance is provided between the contact surface of the central processor and the surface of the body having the conductive region.

In an embodiment of the present invention, when the control rod is moved from the first position to the second position, and the central processor is carried on the positioning members, the first end of each positioning member moves closer to the frame body, so that The contact surface of the central processor has a second distance from the surface of the base, wherein the second distance is less than the first distance.

In an embodiment of the present invention, each of the positioning members further has a carrying portion located on a side close to the opening. The carrier is located between the first end and the second end for carrying the central processor.

In an embodiment of the present invention, the positioning structure further includes at least two first control components. The first control components are disposed corresponding to the positioning members for controlling the first ends of the positioning members to protrude into the opening or to be retracted into the frame body, so that the central processing unit falls from the frame body to the seat body, so that the central processing unit The contact surface abuts the conduction area.

In an embodiment of the novel creation, the first control component includes a first control key and a first elastic component. The first control button is movably disposed on the frame. A portion of the first control key is located within the frame and is coupled to the second end of the corresponding positioning member. The first elastic member is sleeved on the corresponding positioning member and located in the frame body.

In an embodiment of the present invention, the positioning structure further includes at least two clamping members and at least two second control components. The clamping members are movably disposed on the frame. These second control components are arranged corresponding to the clamps.

In an embodiment of the novel creation, the second control component includes a second control key and a second elastic component. The second control button is movably disposed on the frame. A portion of the second control button is located within the frame and is coupled to the corresponding clip. The second elastic member is sleeved on the corresponding clamping member and located in the frame body.

In an embodiment of the present invention, the frame is pivotally connected to the base.

The present invention proposes a motherboard that is suitable for locating a central processor. The central processor has a contact surface. The motherboard includes a body and a connector disposed on the body. The connector includes a seat body. The base has a conductive area, at least two positioning portions, and at least two bearing portions. The two positioning portions are located on opposite sides of the conductive region. Each of the carrying portions is connected to a corresponding positioning portion and is adapted to carry a central processor above the conductive region. When the central processing unit is carried on the two carrying portions, the contact surface faces the conductive area, and each of the carrying portions is adapted to be bent and deformed toward the conductive area of the base to enable the central processing unit after the central processor moves away from the respective carrying portions. The contact surface abuts the conduction area.

In an embodiment of the present invention, the portion of each of the above-described load-bearing portions that is orthographically projected on the base falls within the conductive region.

Based on the above, the positioning structure of the novel creation can be preliminarily determined through the positioning component. The central processing unit is above the conductive area of the connector body and moves through the positioning member relative to the frame body, so that the central processing unit can fall from the frame body to the seat body and contact surface thereof at an appropriate distance. Abutting the conduction area helps to improve the accuracy and stability of the installation of the central processor to the connector. On the other hand, the connector on the motherboard of the present invention can preliminarily position the central processing unit above the conduction area of the base of the connector through the carrying portion, and can be bent and deformed through the carrying portion toward the conduction area of the base body. The central processor can fall from the various load-bearing parts to the seat body at an appropriate distance and abut the conductive area with the contact surface thereof, thereby contributing to the improvement of the accuracy and stability when the central processor is mounted to the connector.

The above described features and advantages of the present invention will become more apparent and understood from the following description.

2‧‧‧ motherboard

2a‧‧‧ Ontology

10‧‧‧Central processor

11‧‧‧Contact surface

12‧‧‧ Non-contact surface

13‧‧‧ convex

20‧‧‧Connector

21‧‧‧ body

21a‧‧‧Surface

22‧‧‧Connected area

23‧‧‧ Positioning Department

24, 124‧‧ ‧ Carrying Department

100, 100A~100B, 100c‧‧‧ positioning structure

110, 110a, 110b‧‧‧ frame

111, 111a, 111b‧‧‧ openings

112, 112a‧‧‧ outer side wall

113‧‧‧ slotting

114a‧‧‧ inner side wall

120, 120a, 120b‧‧‧ positioning parts

121, 121a, 121b‧‧‧ first end

121c‧‧‧ coupling

122, 122a, 122b‧‧‧ second end

123‧‧‧Connecting Department

125‧‧‧Flexible parts

126‧‧‧ hollow column

127‧‧‧rails

130‧‧‧Control lever

131‧‧‧Pushing Department

140‧‧‧First control component

141‧‧‧First control button

142‧‧‧First elastic parts

143‧‧‧ protruding structure

150‧‧‧Clamping parts

160‧‧‧Second control component

161‧‧‧Second control button

162‧‧‧Second elastic parts

163‧‧‧ protruding structure

D1‧‧‧First distance

D2‧‧‧Second distance

P1‧‧‧ first position

P2‧‧‧ second position

FIG. 1 illustrates a state in which the positioning structure of the present invention is positioned to position the central processor to the connector.

2A-2D are cross-sectional views showing the process of positioning the central processor to the connector of the positioning structure of FIG. 1.

3A-3B are cross-sectional views showing a process of positioning a central processing unit to a connector by a positioning structure of another embodiment of the present invention.

4A-4B are cross-sectional views showing a process of positioning a central positioning processor placed on a connector in a positioning structure according to still another embodiment of the present invention.

5A to 5C are cross-sectional views showing a process of positioning a central processing unit to a connector by a positioning structure according to still another embodiment of the present invention.

6A-6B illustrate, in cross section, a process of positioning a central processing unit to a connector by a positioning structure of the present invention.

7A-7C are cross-sectional views showing a further embodiment of the present invention for positioning a central processing unit to a connector of a motherboard.

FIG. 1 illustrates a state in which the positioning structure of the present invention is positioned to position the central processor to the connector. Referring to FIG. 1, in the present embodiment, the positioning structure 100 is adapted to position the central processing unit 10 above the conductive area 22 of the base 21 of the connector 20. The positioning structure 100 can include a frame 110 and at least two positioning members 120. FIG. 1 schematically illustrates four positioning members 120 disposed on the frame 110, but the present invention does not limit the number of the positioning members 120. Any aspect in which at least two or more positioning members 120 are disposed in pairs on opposite sides of the opening 111 of the housing 110 is suitable for the novel creation.

The casing 110 is, for example, a hollow casing. Each of the positioning members 120 has a first end portion 121 that is relatively away from the frame body 110 and a second end portion 122 that is located in the frame body 110. In other words, the frame 110 is provided with openings corresponding to the number of the positioning members 120 so that the respective positioning members 120 are disposed through the corresponding openings. The first end portion 121 of each of the positioning members 120 protrudes from the corresponding opening from the frame 110. Here, the second end portion 122 of any two adjacent positioning members 120 can pass through the plurality of connecting portions 123 located in the housing 110 (FIG. 1) Three) are schematically shown and connected to each other. The connecting portions 123, such as the positioning members 120 and the second end portions 122 connecting the two adjacent positioning members 120, are generally U-shaped.

With continued reference to FIG. 1, each of the positioning members 120 is movable relative to the frame 110, and the actuation mechanism thereof is explained below. In the embodiment, the positioning structure 100 further includes a control rod 130. The control rod 130 is disposed through the slot 113 on the outer side wall 112 of the frame 110, that is, a part of the control rod 130 protrudes from the frame 110, and the other part of the control rod 130 is located in the frame 110. It should be noted that the portion of the lever 130 located in the frame 110 is the pushing portion 131. The pushing portion 131 is adapted to reciprocate between the first position P1 and the second position P2 relative to the frame 110 along the slot 113 and corresponding to the second end 122 of one of the positioning members 120. The control rod 130 illustrated in FIG. 1 is located at the first position P1, and the pushing portion 131 at this time pushes against the second end portion 122 of the corresponding positioning member 120. Since the positioning members 120 are connected to each other, after the second end portion 122 of one of the positioning members 120 is pushed by the pushing portion 131, the positioning members 120 can be lifted at the same time. At this time, the first end portion 121 of each of the first positioning members 120 will move away from the frame. On the contrary, when the control lever 130 moves from the first position P1 to the second position P2, the pushing portion 131 will no longer push against the second end portion 122 of the corresponding positioning member 120, so that the first of the first positioning members 120 is first. The end portion 121 moves in a direction toward the frame body 110. The pushing portion 131 of the lever 130 located at the second position P2 is, for example, still abutting against the second end portion 122 of the corresponding positioning member 120, or maintaining a proper spacing.

In this embodiment, each of the positioning members 120 further has a proximity to the opening 111. The bearing portion 124 on one side. Each of the receiving portions 124 is located between the first end portion 121 and the second end portion 122 of the corresponding positioning member 120 and is located outside the frame 110 . Each carrier portion 124 is primarily used as a carrier central processor 10.

2A-2D are cross-sectional views showing the process of positioning the central processor to the connector of the positioning structure of FIG. 1. Referring to FIG. 2A , when the frame 110 is placed on the base 21 , the opening 111 of the frame 110 is, for example, a conductive area 22 surrounding the base 21 , and a portion of the bearing portion 124 of each positioning member 120 is located at the opening. 111 and the upper side of the conduction area 22. Next, the contact surface 11 of the central processing unit 10 is placed facing the conduction region 22, and placed on each of the carrier portions 124. When the central processing unit 10 is carried on each of the carrying portions 124, the central processing unit 10 is located, for example, above the opening 111 and the conductive area 22. Specifically, the lever 130 of FIG. 2A is located, for example, at the first position P1 illustrated in FIG. Based on the interaction between the control rod 130 and the positioning member 120, the first end portion 121 of each positioning member 120 is relatively far from the housing 110. Similarly, the carrying portion 124 of each positioning member 120 is also relatively far from the frame 110 such that the contact surface 11 of the central processing unit 10 and the surface 21a of the base portion 21 having the conductive region 22 have a first distance D1. In this way, the central processing unit 10 can be accurately positioned above the conductive area 22 of the base 21 through the positioning structure 100.

Next, referring to FIG. 2B, the control rod 130 of FIG. 2B is, for example, located at the second position P2 illustrated in FIG. Based on the interaction between the control rod 130 and the positioning member 120, it can be known that, in the case that the pushing portion 131 does not push against the second end portion 122 of the corresponding positioning member 120, the first end of each positioning member 120 Department 121 will be relative Close to the frame 110. Similarly, the bearing portion 124 of each positioning member 120 is also relatively close to the frame body 110 such that the contact surface 11 of the central processing unit 10 and the surface 21a of the base body 21 have a second distance D2. The second distance D2 is smaller than the first distance D1. In this way, the central processing unit 10 that is accurately positioned above the conductive region 22 of the base 21 through the positioning structure 100 can be closer to the conductive region 22 of the base 21.

Referring to FIG. 2C and FIG. 2D simultaneously, after the central processing unit 10 is brought closer to the conduction region 22 of the base 21, the non-contact surface 12 of the central processing unit 10 (ie, the surface opposite to the contact surface 11) may be slightly applied. ). For example, each of the carrying portions 124 is made of a flexible material, for example, after the non-contact surface 12 of the central processing unit 10 is applied, the respective carrying portions 124 can be bent and deformed toward the base 21 (for example, elastic deformation). . Thereby, after the respective carrier portions 124 are elastically deformed, the central processing unit 10 can be removed from the respective carrier portions 124 and fall into the conduction regions 22 of the base body 21. In this way, the contacts (not shown) disposed on the contact surface 11 of the central processing unit 10 and the terminals (not shown) in the conduction region 22 can abut each other.

Compared with the general method of manually assembling the central processing unit to the connector on the circuit board, the novel creation positioning structure can mechanically control and position the central processing unit in the conduction area of the connector body. Therefore, it is possible to effectively prevent the terminal disposed in the conduction area from being inadvertently damaged when positioning and placing the central processing unit on the connector body.

Other embodiments are listed below for illustration. It is to be noted that the following embodiments use the same reference numerals and parts of the foregoing embodiments, in which the same reference numerals are used to refer to the same or similar elements, and the same technique is omitted. Description of the capacity. For the description of the omitted portions, reference may be made to the foregoing embodiments, and the following embodiments are not repeated.

3A-3B are cross-sectional views showing a process of positioning a central processing unit to a connector by a positioning structure of another embodiment of the present invention. Referring to FIG. 3A firstly, different from the positioning structure 100 of the above embodiment, the first end portion 121a of each positioning member 120a of the positioning structure 100A of the present embodiment is adapted to protrude into the opening 111a or to be retracted into the frame 110a. In detail, the frame 110a is, for example, an opening corresponding to the number of the positioning members 120a (two of which are schematically illustrated in FIGS. 3A and 3B) on the inner side wall 114a for defining the opening 111a, so that the respective positioning is performed. The piece 120a is threaded through the corresponding opening.

On the other hand, the positioning structure 100A further includes at least two first control components 140 (two are schematically illustrated in FIGS. 3A and 3B). The number of first control assemblies 140 corresponds to the number of locators 120a. These first control components 140 are disposed corresponding to the positioning members 120a. In the present embodiment, each of the first control components 140 may include a first control key 141 and a first elastic member 142. The first control key 141 is movably disposed on the housing 110a. An opening corresponding to the number of the first control keys 141 is formed in the outer wall 112a of the frame body 110a with respect to the inner side wall 114a. Each of the first control keys 141 is, for example, an opening that is disposed through the corresponding outer sidewall 112a and is coupled to a corresponding second end 122a located within the housing 110a. For example, each of the first control keys 141 may be a structure integrally formed with the corresponding positioning member 120a.

As shown in FIG. 3A, the junction of each of the first control keys 141 and the corresponding second end portion 122a has a protruding structure 143. Each of the first elastic members 142 is sleeved on the corresponding positioning member 120a and is limited to the frame 110a. As shown in Figure 3B, each The protruding structures 143 are, for example, perpendicular to the corresponding positioning members 120a, and each of the first elastic members 142 is limited between the inner side wall 114a and the corresponding protruding structure 143.

As shown in FIG. 3A, when the portions where the respective first control keys 141 are exposed to the outer side wall 112a are pressed, the corresponding first end portions 121a thereof protrude into the opening 111a and are located above the conduction regions 22 of the seat body 21. On the other hand, each of the protruding structures 143 is moved toward the inner side wall 114a such that the corresponding first elastic member 142 is compressed by the pushing of the protruding structure 143. Next, the contact surface 11 of the central processing unit 10 is placed facing the conduction region 22, and placed on the first end portion 121a of each of the insertion openings 111a. When the central processing unit 10 is carried on the first end portion 121a of each of the insertion openings 111a, the central processing unit 10 can be accurately positioned above the conduction area 22. In another embodiment, since the first control keys 141 are pressed and protrude into the first end portion 121a of the opening 111a, the central processing unit 10 can also be positioned above the conduction region 22 by clamping.

Referring to FIG. 3B, after the central processing unit 10 is accurately positioned above the conduction area 22 of the base 21, the operation of pressing the respective first control keys 141 is released. At this time, the elastic restoring force of each of the first elastic members 142 will retract the corresponding first end portion 121a into the frame body 110a. In this way, the central processing unit 10 will no longer be carried by the respective first end portions 121a, and then fall into the conduction region 22 of the base body 21, so that the contacts disposed on the contact surface 11 of the central processing unit 10 (Fig. The terminals (not shown) in the conduction region 22 abut each other.

4A-4B are cross-sectional views showing a process of positioning a central positioning processor placed on a connector in a positioning structure according to still another embodiment of the present invention. Please refer to the map first. 4A, the structural configuration of the positioning structure 100B of the present embodiment for positioning the central processing unit 10 above the conductive area 22 and the actuation mechanism thereof are the same as or similar to those of the positioning structure 100A of the above embodiment, and thus will not be described again. On the other hand, for the sake of clarity and convenience of explanation, the positioning member 120a is omitted.

Different from the positioning structure 100A of the above embodiment, the positioning structure 100B of the present embodiment can take out the central processing unit 10 placed on the base 21, and the actuation mechanism thereof is as follows. The positioning structure 100B further includes at least two clamping members 150 (two are schematically illustrated in FIGS. 4A and 4B) and at least two second control assemblies 160 (two are schematically illustrated in FIGS. 4A and 4B). These clamping members 150 are disposed corresponding to the second control components 160, so the number of the two is corresponding. Each of the clamping members 150 is movably disposed on the frame 110a and located on opposite sides of the opening 111a. Each of the holding members 150 is adapted to protrude into the opening 111a or to be retracted to the frame 110a. In detail, the frame 110a is, for example, provided with an opening corresponding to the number of the holding members 150 on the inner side wall 114a for defining the opening 111a, so that the respective holding members 150 are bored in the corresponding openings. Here, the clamping members 150 are respectively located on one side of the positioning members 120a, and there is a height difference between the positioning members 120a and the positioning members 120a.

In the present embodiment, each of the second control components 160 may include a second control key 161 and a second elastic member 162. The second control button 161 is movably disposed on the housing 110a. An opening corresponding to the number of the second control keys 161 is formed in the outer wall 112a of the frame body 110a with respect to the inner side wall 114a. Each of the second control keys 161 is, for example, an opening that is disposed through the corresponding outer sidewall 112a and is coupled to a corresponding clip 150 located within the housing 110a. For example, each of the second control keys 161 may be A structure integrally formed with the corresponding holder 150.

As shown in FIG. 4A, the junction of each of the second control keys 161 and the corresponding holder 150 has a protruding structure 163. Each of the second elastic members 162 is sleeved on the corresponding clamping member 150 and is limited to the frame 110a. As shown in FIG. 4B, each of the protruding structures 163 is perpendicular to the clamping member 150, and each of the second elastic members 162 is located between the inner side wall 114a and the corresponding protruding structure 163.

When the portions where the respective second control keys 161 are exposed to the outer side wall 112a are pressed, their corresponding holding members 150 protrude into the opening 111a and are located above the conduction region 22 of the seat body 21. On the other hand, each of the protruding structures 163 is moved toward the inner side wall 114a such that the corresponding second elastic member 162 is compressed by the pushing of the protruding structure 163. The holding members 150 that protrude into the opening 111a abut against the convex portions 13 of the central processing unit 10 (for example, the heat sinks that connect the non-contact faces 12 of the central processing unit 10) placed on the base body 21.

Thereafter, referring to FIG. 4B, each of the second control keys 161 is continuously pressed, and the frame 110a is moved away from the base 21. In this way, the central processing unit 10 held by the holding members 150 can be taken out from the base 21. After the central processor 10 is taken out from the seat body 21, the operation of pressing the second control keys 161 is released. At this time, the elastic restoring force of each of the second elastic members 162 will retract the corresponding gripping members 150 into the frame body 110a. As a result, the central processing unit 10 will no longer be clamped by the clamping members 150 and will fall out of the frame 110a.

5A to 5C are cross-sectional views showing a process of positioning a central processing unit to a connector by a positioning structure according to still another embodiment of the present invention. Please refer to FIG. 5A to FIG. 5C, In this embodiment, for example, the positioning structure 100A is pivotally connected to one side of the base 21. For example, when the first end portion 121a of each of the positioning members 120a protrudes into the opening 111a for carrying the central processing unit 10, the frame 110a and the base 21 may have an acute angle, or the frame 110a may be attached. When it is fitted to the seat body 20.

Specifically, when the frame body 110a is rotated relative to the base body 20 and attached to the base body 20, the central processing unit 10 carried by the respective first end portions 121a extending into the opening 111a can be accurately positioned. Above the conduction region 22 of the body 21. In another embodiment, the positioning structure 100B can also be pivoted to one side of the base 21 to achieve similar technical effects.

After the central processing unit 10 is accurately positioned above the conduction area 22 of the base body 21, the operation of pressing the respective first control keys 141 is released. At this time, the elastic restoring force of each of the first elastic members 142 will retract the corresponding first end portion 121a into the frame body 110a. In this way, the central processing unit 10 will no longer be carried by the respective first end portions 121a, and then fall into the conduction region 22 of the base body 21, so that the contacts disposed on the contact surface 11 of the central processing unit 10 (Fig. The terminals (not shown) in the conduction region 22 abut each other.

6A-6B illustrate, in cross section, a process of positioning a central processing unit to a connector by a positioning structure of the present invention. Referring to FIG. 6A and FIG. 6B, in the embodiment, the first end portion 121b of each positioning member 120b of the positioning structure 100c is connected to the second end portion 122b by an elastic member 125. Each of the first end portions 121b is located on a side close to the opening 111b. Each of the first ends 121b can be used to carry the central processor 10 and is adapted to move relative to the hollow post 126 of the keeper 120b.

When the central processing unit 10 is carried on the first end portions 121b and the respective first end portions 121b are moved toward the frame body 110b, the respective elastic members 125 are compressed by the corresponding first end portions 121b. On the other hand, each of the first end portions 121b is coupled to the guide rail 127 in the corresponding hollow column 126 by the coupling portion 121c, for example, when each of the first end portions 121b moves toward the frame 110b, each first end portion The 121b can be retracted to the corresponding hollow post 126 by the guidance of the corresponding rail 127. When the first end portion 121b of each of the positioning members 120b is retracted into the corresponding hollow post 126, the central processing unit 10 will no longer be carried by the first end portions 121b and fall into the conduction region 22 of the seat body 21. In this way, the contacts (not shown) disposed on the contact surface 11 of the central processing unit 10 and the terminals (not shown) in the conduction region 22 can abut each other.

7A-7C are cross-sectional views showing a further embodiment of the present invention for positioning a central processing unit to a connector of a motherboard. Referring first to FIG. 7A, in the present embodiment, the motherboard 2 includes a body 2a and a connector 20 disposed on the body 2a, wherein the connector 20 includes a base 21. The base 21 is fixed to the body 2a and has a conductive area 22, at least two positioning portions 23, and at least two carrying portions 24. The two positioning portions 23 are located on opposite sides of the conductive region 22. Each of the carrying portions 24 is connected to the corresponding positioning portion 23 and is located above the conductive portion 22 . That is, the load-bearing portion 24 is maintained at a distance from the surface 21a having the conductive region 22, and the orthographic projection portion of each of the load-bearing portions 24 on the seat body 21 falls within the conductive region 22. The user can face the contact surface 11 of the central processing unit 10 against the conductive area 22 to be placed on each of the carrying portions 24. When the central processing unit 10 is carried on each of the carrying units 24, the central processing unit 10 is, for example, turned on. Above the area 22.

Next, referring to FIG. 7B and FIG. 7C, after the central processing unit 10 is carried on each of the carrying portions 24, the non-contact surface 12 of the central processing unit 10 (ie, the surface opposite to the contact surface 11) may be slightly applied. . For example, each of the carrying portions 24 is made of a flexible material, for example, so that after the non-contact surface 12 of the central processing unit 10 is applied, the respective carrying portions 24 can be bent and deformed toward the conductive region 22 of the base body 21 ( For example, elastic deformation). Thereby, after the respective carrier portions 24 are elastically deformed, the central processing unit 10 can be removed from the respective carrier portions 24 and fall into the conduction region 22 of the base body 21. In this way, the contacts (not shown) disposed on the contact surface 11 of the central processing unit 10 and the terminals (not shown) in the conduction region 22 can abut each other.

In summary, the positioning structure of the present invention can initially position the central processing unit above the conduction area of the connector body through the positioning member, and through the movement of the positioning member relative to the frame body, so that the central processing unit can be properly The distance from the frame to the seat body and the contact surface abuts the conduction area, thereby helping to improve the accuracy and stability of the installation of the central processing unit to the connector. To put it another way, since the positioning structure created by the present invention is mechanically controlled to position and place the central processing unit in the conduction area of the connector body, it is possible to effectively avoid positioning and placing the central processing unit in the connector. The seat is inadvertently damaged by the terminal disposed in the conductive area.

On the other hand, the connector on the motherboard of the present invention can preliminarily position the central processing unit above the conduction area of the base of the connector through the carrying portion, and can be bent and deformed through the carrying portion toward the conduction area of the base body. The central processor can Appropriate distances can fall from the various load-bearing parts onto the seat body and abut the contact area with its contact surface, thus helping to improve the accuracy and stability when installing the central processor to the connector.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the novel creation, and any person skilled in the art can make some changes without departing from the spirit and scope of the novel creation. Retouching, the scope of protection of this new creation is subject to the definition of the scope of the patent application attached.

10‧‧‧Central processor

11‧‧‧Contact surface

12‧‧‧ Non-contact surface

13‧‧‧ convex

20‧‧‧Connector

21‧‧‧ body

22‧‧‧Connected area

100‧‧‧ Positioning structure

110‧‧‧ frame

111‧‧‧ openings

112‧‧‧Outer side wall

113‧‧‧ slotting

120‧‧‧ positioning parts

121‧‧‧First end

122‧‧‧second end

123‧‧‧Connecting Department

124‧‧‧Loading Department

130‧‧‧Control lever

131‧‧‧Pushing Department

P1‧‧‧ first position

P2‧‧‧ second position

Claims (11)

A positioning structure is adapted to position a central processing unit above a conductive area of a body of a connector, the central processing unit having a contact surface, the positioning structure comprising: a frame having an opening; and at least two The positioning member is movably disposed on the frame, the at least two positioning members are adapted to carry the central processor above the opening, and each of the positioning members has a first end and a second end. When the body is placed on the base body, and the central processor is carried on the at least two positioning members, the opening surrounds the conductive area, and the contact surface faces the conductive area, the first end of each of the positioning members The portion is adapted to move closer to the frame to abut the contact area of the central processing unit after the central processor moves away from the positioning members. The positioning structure of claim 1, wherein the second ends of the at least two positioning members are connected to each other, the positioning structure further comprises: a control rod movably disposed on the frame, the control The lever has a pushing portion located in the frame, and the pushing portion is disposed corresponding to the second end of one of the at least two positioning members, the lever being adapted to be in a first position and a second position Reciprocating motion, when the control rod is located at the first position, and the central processor is carried on the at least two positioning members, the pushing portion pushes against the second end of one of the at least two positioning members The first end of each of the positioning members is moved away from the frame such that the contact surface of the central processor has a first distance from a surface of the base having the conductive region. The positioning structure of claim 2, wherein when the lever is moved from the first position to the second position, and the central processor is carried on the at least two positioning members, each of the positioning members The first end moves closer to the frame such that the contact surface of the central processor has a second distance from the surface of the base, wherein the second distance is less than the first distance. The positioning structure of claim 1, wherein each of the positioning members further has a bearing portion on a side close to the opening, the bearing portion being located between the first end portion and the second end portion, Used to carry the central processor. The positioning structure of claim 1, further comprising: at least two first control components, corresponding to the at least two positioning components, for controlling the first ends of the at least two positioning components to extend into the Opening or contracting to the frame, the central processor is dropped from the frame onto the base such that the contact surface of the central processing unit abuts the conductive area. The positioning structure of claim 5, wherein each of the first control components comprises: a first control button movably disposed on the frame, the portion of the first control button being located in the frame, and The second end portion of the corresponding positioning member is connected; and a first elastic member is sleeved on the corresponding positioning member and located in the frame. The positioning structure of claim 5, further comprising: at least two clamping members movably disposed on the frame; and at least two second control components disposed corresponding to the at least two clamping members. The positioning structure described in claim 7 of the patent scope, wherein each of the second controls The assembly includes: a second control button movably disposed on the frame, a portion of the second control button being located in the frame, and connecting the corresponding clamping member; and a second elastic member disposed on the frame Corresponding to the clamping member, and located in the frame. The positioning structure of claim 5, wherein the frame is pivotally connected to the base. A motherboard having a positioning structure, the positioning structure is suitable for positioning a central processing unit, the central processing unit has a contact surface, the main board includes: a body; a connector is disposed on the body, the connector comprises a body having a conductive area above the body; and a positioning structure disposed on the connector, comprising a frame having an opening and at least two positioning members, wherein the at least two positioning members are movably disposed on the frame And locating the central processing unit above the opening, each of the positioning members has a first end portion and a second end portion; wherein the frame body of the positioning structure is placed on the seat of the connector When the central processing unit is carried on the at least two positioning members, the opening surrounds the conductive area, and the contact surface of the central processor faces the conductive area, and the first end of each of the positioning members Suitable for moving close to the frame to abut the contact area of the central processing unit after the central processor moves away from the positioning members. The motherboard according to claim 10, wherein each of the positioning members further has a bearing portion on a side close to the opening, and each of the bearing portions is casted on the seat. The portion of the shadow falls within the conductive area.