CN111657695B - Computer cabin and adjusting method thereof - Google Patents

Abstract

The invention provides a computer cabin and an adjusting method thereof. The cabin body comprises a seat, a back and a display interface. The seat, the back and the display interface are movably arranged on the cabin body. The display interface and the chair back are respectively positioned at two opposite sides of the chair seat. The driving module is arranged on the cabin body. The sensing module is disposed on the cabin body and configured to provide sensing data. The sensing data comprises a seat pressure sensing value and a back pressure sensing value. The control module is electrically connected with the driving module and the sensing module and is configured to send an adjustment instruction according to the sensing data. The driving module is configured to receive the adjustment instruction to synchronously rotate the seat, the seat back and the display interface to the working angle and reduce the difference between the seat back pressure sensing value and the seat back pressure sensing value.

Description

Computer cabin and adjusting method thereof

Technical Field

The present disclosure relates to computer cabins, and particularly to a computer cabin and an adjusting method thereof.

Background

With the rise of the electronic competition industry, more and more products are generated correspondingly, and in order to make the electronic competition hands have more comfortable environment, vendors develop products such as computer cabins. The computer cabin provides higher comfort for the user, and can meet the requirement that the user sits on the computer cabin for a long time, thereby providing higher enjoyment for the user. However, in the existing computer cabin, the reclining angles of the seat, the backrest and the display interface cannot be adjusted correspondingly according to the needs of different users, in other words, the reclining angles of the seat, the backrest and the display interface lack an automatic adjustment mechanism conforming to ergonomics, so that the comfort of the computer cabin is poor.

Disclosure of Invention

The invention provides a computer cabin and an adjusting method thereof, which can automatically adjust the lying angle of a chair seat, a chair back and a display interface so as to accord with ergonomics and help to promote the comfort of a user using the computer cabin.

The computer cabin comprises a cabin body, a driving module, a sensing module and a control module. The cabin body comprises a seat, a back and a display interface. The seat, the back and the display interface are movably arranged on the cabin body. The display interface and the chair back are respectively positioned at two opposite sides of the chair seat. The driving module is arranged on the cabin body. The sensing module is disposed on the cabin body and configured to provide sensing data. The sensing data comprises a seat pressure sensing value and a back pressure sensing value. The control module is electrically connected with the driving module and the sensing module and is configured to send an adjustment instruction according to the sensing data. The driving module is configured to receive the adjustment instruction to rotate the seat, the seat back and the display interface to a working angle and reduce a pressure difference between the seat back pressure sensing value and the seat back pressure sensing value.

The computer cabin adjusting method is used for adjusting the computer cabin. The computer cabin adjusting method comprises the step of providing sensing data through a sensing module, wherein the sensing data comprises a seat pressure sensing value and a back pressure sensing value. The judgment is performed by the control module, including judging whether the sensed data exceeds a preset value. And sending an adjustment instruction through the control module, wherein when the control module judges that the sensing data exceeds a preset value, the control module sends the adjustment instruction. The driving module receives the adjusting instruction and adjusts the adjusting instruction so as to enable the chair seat, the chair back and the display interface to synchronously rotate from a preset angle (default angle) to a working angle.

In an embodiment of the present invention, the seat and the backrest are pivotally connected to the cabin body by an axis, and when the seat, the backrest and the display interface are located at the working angle, the following relationships are satisfied: w2sin (θ1+θ2) l2=w1cos (θ2) L1. W1 is the first pressure to which the seat is subjected. W2 is the second pressure exerted by the chair back. θ1 is the initial angle of the seatback. θ2 is the working angle. L1 is a first horizontal distance between the force receiving position of the first pressure and the axis. L2 is a second horizontal distance between the force receiving position and the axis of the second pressure.

In an embodiment of the invention, the sensing module includes a seat pressure sensor disposed on the seat and electrically connected to the control module, and is configured to sense a pressure applied to the seat and correspondingly generate a seat pressure sensing value.

In an embodiment of the invention, the sensing module includes a back pressure sensor disposed on the seat back and electrically connected to the control module, and is configured to sense a pressure applied to the seat back and correspondingly generate a seat back pressure sensing value.

In an embodiment of the invention, the cabin body further includes a headrest connected to the seatback. The sensed data also includes a headrest pressure sensing value. The sensing module comprises a headrest pressure sensor, is arranged on the headrest and electrically connected with the control module, and is configured to sense the pressure born by the headrest and correspondingly generate a headrest pressure sensing value.

In an embodiment of the invention, the sensing data further includes a human body position sensing value. The sensing module comprises a human body infrared sensor, is arranged on the cabin body and is electrically connected with the control module, and is configured to sense whether a user is positioned above the seat and correspondingly generate a human body position sensing value.

In an embodiment of the invention, the cabin body further includes a headrest connected to the seatback. The sensed data also includes a head position sensed value and/or an eye position sensed value. The sensing module comprises a head infrared sensor which is arranged on the cabin body and electrically connected with the control module and is configured to sense whether the head of a user is positioned in front of the headrest and correspondingly generate a head position sensing value and/or configured to sense the position of eyes of the user and correspondingly generate an eye position sensing value.

In an embodiment of the invention, the adjustment command includes a working angle adjustment command. The driving module comprises a gesture adjusting driver which is arranged on the cabin body, is coupled with the seat and the chair back, is electrically connected with the control module, and is configured to receive a working angle adjusting instruction so as to synchronously rotate the seat, the chair back and the display interface to a working angle.

In an embodiment of the invention, the control module includes a storage unit and a micro control unit. The storage unit is configured to store a lookup table. The micro control unit is electrically connected with the driving module, the sensing module and the storage unit and is configured to send an adjustment instruction according to the sensing data and the comparison table.

In an embodiment of the invention, the backrest and the display interface are rotatably connected to the seat, the backrest and the display interface have initial angles relative to the seat, and the comparison table includes a difference value, an initial angle and a working angle corresponding to the difference value and the initial angle.

In an embodiment of the invention, the display interface is rotatably disposed on the cabin body. The adjustment instruction includes a display interface rotation instruction. The driving module comprises a display interface rotation driver, is arranged on the cabin body, is coupled with the display interface, is electrically connected with the control module, and is configured to receive a display interface rotation instruction so as to enable the display interface to rotate and face the chair back.

In an embodiment of the invention, the display interface is slidably disposed on the cabin body. The adjustment instruction includes a display interface sliding instruction. The driving module comprises a display interface sliding driver, is arranged on the cabin body, is coupled with the display interface, is electrically connected with the control module, and is configured to receive a display interface sliding instruction to adjust the height of the display interface.

In an embodiment of the present invention, the seat back is rotatably provided with a cabin body. The adjustment instructions include a chair back rotation instruction. The driving module comprises a chair back rotating driver, is arranged on the cabin body, is coupled with the chair back, is electrically connected with the control module, and is configured to receive a chair back rotating instruction so as to enable the chair back and the chair seat to rotate and face the display interface.

In an embodiment of the invention, the display interface includes a projection screen. The computer cabin further comprises a projector which is arranged above the cabin body of the cabin, and the projection cloth curtain and the projector are respectively positioned on two opposite sides of the chair seat.

Based on the above, in the computer cabin and the adjusting method thereof of the present invention, the sensing module is disposed on the cabin body and configured to provide sensing data. The sensing data comprises a seat pressure sensing value and a back pressure sensing value. The control module is electrically connected with the driving module and the sensing module and is configured to send an adjustment instruction according to the sensing data. The driving module is configured to receive the adjustment instruction to rotate the seat, the seat back and the display interface to the working angle and reduce the difference between the seat back pressure sensing value and the seat back pressure sensing value. Therefore, the angles of the chair seat, the chair back and the display interface can be automatically adjusted to accord with ergonomics, and the comfort of a user using the computer cabin can be improved.

In order to make the above features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

Fig. 1 is a schematic diagram of a computer cabin according to an embodiment of the invention.

Fig. 2 is a circuit block diagram of the computer cabin of fig. 1.

Fig. 3A and 3B show the operation principle of the computer cabin of fig. 1.

Fig. 4 is a flowchart of a computer cabin adjusting method according to an embodiment of the invention.

FIG. 5 is a block diagram of a computer cabin adjusting method according to an embodiment of the invention.

Fig. 6A is a schematic side view of a computer cabin according to another embodiment of the invention.

Fig. 6B is a schematic top view of the computer cabin of fig. 6A.

FIG. 7 is a circuit block diagram of the computer cabin of FIG. 6A.

Fig. 8 is a schematic view of a computer cabin according to yet another embodiment of the invention.

[ symbolic description ]

100. 300, 400: computer cabin

110. 310, 410: cabin body

111. 311, 411: chair seat

112. 312, 412: chair back

113. 313: headrest for head

115. 315, 415: display interface

120. 320: driving module

121. 321: posture adjustment driver

122: display interface rotary driver

123. 323: display interface sliding driver

326: chair back rotary driver

130. 330: sensing module

131. 331: chair seat pressure sensor

132. 332: chair back pressure sensor

133. 333). Headrest pressure sensor

134. 334, 334: human body infrared sensor

135. 335: head infrared sensor

140. 340: control module

141. 341: memory cell

142. 342: micro control unit

150. 350: reset key

460: projector with a light source

A1: an axis line

A2: an axis line

A3: an axis line

AX: axial direction

D: sensing data

D1: chair seat pressure sensing value

D2: chair back pressure sensing value

D3: headrest pressure sensing value

D4: human body position sensing value

D5: head position sensing value

D6: eye position sensing value

L1: first horizontal distance

L2: second horizontal distance

R: reset signal

RS: reset instruction

S: adjustment instructions

S1: work angle adjustment instruction

S2: display interface rotation instruction

S3: display interface sliding instruction

S6: chair back rotation instruction

SI: line of sight

S210 to S240: step (a)

W1: first pressure of

W2: second pressure

θ1: initial angle

θ2: working angle

Detailed Description

Fig. 1 is a schematic diagram of a computer cabin according to an embodiment of the invention. Fig. 2 is a circuit block diagram of the computer cabin of fig. 1. Referring to fig. 1 and 2, the computer cabin 100 of the present embodiment includes a cabin body 110, a driving module 120, a sensing module 130 and a control module 140. The cabin body 110 includes a seat 111, a back 112, and a display interface 115. The seat 111, the back 112 and the display interface 115 are movably disposed on the cabin body 110. The display interface 115 and the backrest 112 are respectively located on opposite sides of the seat 111 (i.e. the display interface 115 is located in front of the seat 111 and the backrest 112 is located behind the seat 111). The driving module 120 and the sensing module 130 are disposed on the cabin body 110. The sensing module 130 is configured to provide sensing data D. The sensing data D may include a seat pressure sensing value D1 and a back pressure sensing value D2. The control module 140 is electrically connected to the driving module 120 and the sensing module 130, and is configured to send an adjustment command S according to the sensing data D. The driving module 120 is configured to receive the adjustment command S to synchronously rotate the seat 111, the backrest 112, and the display interface 115 to the working angle θ2 and reduce the difference between the backrest pressure sensing value D2 and the seat pressure sensing value D1. For example, the difference between the seat back pressure sensing value D2 and the seat pressure sensing value D1 may decrease and approach zero. Accordingly, the computer cabin 100 of the present embodiment can automatically adjust the lying angles of the seat 111, the backrest 112 and the display interface 115 to conform to the ergonomics, which is helpful for improving the comfort of the user using the computer cabin 100.

Fig. 3A and 3B show the operation principle of the computer cabin of fig. 1. Referring to fig. 1, 3A and 3B, the backrest 112 and the display interface 115 of the present embodiment may have an initial angle θ1 with respect to the seat 111. Of course, the seatback 112 and the display interface 115 may not have the initial angle θ1 (or the initial angle θ1 is equal to zero). The seat 111 and the back 112 are pivotally connected to the cabin 110 along an axis A1 and driven by a posture adjustment driver 121 of the driving module 120. The display interface 115 includes, but is not limited to, the display interface 115 displayed by a display screen of a display.

As shown in fig. 3A, when a user sits on the seat 111 and leans against the backrest 112, the seat 111 receives a first pressure W1, and the backrest 112 receives a second pressure W2. A first horizontal distance L1 exists between the force receiving position of the first pressure W1 and the axis A1. A second horizontal distance L2 exists between the force receiving position of the second pressure W2 and the axis A1.

As shown in fig. 3B, when the seat 111, the backrest 112 and the display interface 115 are positioned at the working angle θ2, the first pressure W1 and the second pressure W2 applied to the seat 111 and the backrest 112 are balanced with each other to satisfy the following relationship: w2sin (θ1+θ2) l2=w1cos (θ2) L1. Accordingly, since the first pressure W1 and the second pressure W2 are balanced with each other, the user does not feel uncomfortable, and the comfort of the user using the computer cabin 100 is improved.

Referring to fig. 2, in the present embodiment, the control module 140 includes a storage unit 141 and a micro control unit 142 (Microcontroller Unit, MCU). The storage unit 141 is configured to store a lookup table. The micro-control unit 142 is electrically connected to the driving module 120, the sensing module 130 and the storage unit 141, and the micro-control unit 142 is configured to send an adjustment command S according to the sensing data D and the lookup table.

In an embodiment of the invention, the comparison table includes a difference value and a working angle θ2 corresponding to the difference value. The micro-control unit 142 can find the target difference (e.g., between 0 and 5), and correspondingly adjust the seat 111, the backrest 112, and the display interface to the working angle θ2. Furthermore, the micro control unit 142 is configured to allow the difference to be within a specific range. The reason is that, if the difference is set to zero, the micro control unit 142 will cause the user to feel uncomfortable only due to the minimal shake, i.e. the adjustment of the working angle θ2 is performed on the computer cabin 100.

In an embodiment of the invention, the comparison table includes a difference value, an initial angle θ1, and a working angle θ2 corresponding to the difference value and the initial angle θ1. The micro-control unit 142 can find a target difference (e.g., between 0 and 5), and correspondingly adjust the seat 111, the back 112, and the display interface to the working angle θ2 according to the initial angle θ1 of the back 112 and the display interface 115.

Referring to fig. 1 and 2, in the present embodiment, the cabin body 110 further includes a headrest 113 connected to the seatback 112. The sensing module 130 is configured to provide sensing data D. The sensing data D further includes a headrest pressure sensing value D3 and a human body position sensing value D4. The sensing module 130 includes a seat pressure sensor 131, a seat back pressure sensor 132, a headrest pressure sensor 133, a human body infrared sensor 134, and a head infrared sensor 135.

In the present embodiment, the seat pressure sensor 131 is disposed on the seat 111 and electrically connected to the micro control unit 142 of the control module 140, and is configured to sense the pressure applied to the seat 111 and correspondingly generate a seat pressure sensing value D1. The back pressure sensor 132 is disposed on the seat back 112 and electrically connected to the micro control unit 142 of the control module 140, and is configured to sense the pressure applied by the seat back 112 and correspondingly generate a seat back pressure sensing value D2. The headrest pressure sensor 133 is disposed on the headrest 113 and electrically connected to the micro control unit 142 of the control module 140, and is configured to sense a pressure applied to the headrest 113 and correspondingly generate a headrest pressure sensing value D3.

In this embodiment, the sensing data D further includes a head position sensing value D5 and/or an eye position sensing value D6. The human body infrared sensor 134 is disposed on the cabin body 110 and electrically connected to the micro control unit 142 of the control module 140, and is configured to sense whether the user is located above the seat 111 and correspondingly generate a human body position sensing value D4. The head infrared sensor 135 is disposed on the cabin body 110 and electrically connected to the control module 140, and is configured to sense whether the head of the user is located in front of the headrest 113 and correspondingly generate a head position sensing value D5, and/or is configured to sense the position of the eyes of the user and correspondingly generate an eye position sensing value D6.

Referring to fig. 1 and 2, the display interface 115 of the present embodiment is movably disposed on the cabin body 110. For example, the display interface 115 is rotatably disposed on the cabin body 110 along the axis A2 to rotate close to or away from the seat back 112, and the display interface 115 is slidably disposed on the cabin body 110 along the axis AX to be suitable for adjusting the height. The adjustment command S includes a working angle adjustment command S1, a display interface rotation command S2, and a display interface sliding command S3. The driving module 120 includes a gesture adjustment driver 121, a display interface rotation driver 122, and a display interface sliding driver 123. Gesture adjustment driver 121, display interface rotation driver 122, and display interface slide driver 123 include, but are not limited to, motors.

In the present embodiment, the posture adjustment driver 121 is disposed on the cabin body 110, coupled to the seat 111 and the backrest 112, and electrically connected to the micro control unit 142 of the control module 140, and configured to receive the operation angle adjustment command S1 to synchronously rotate the seat 111, the backrest 112, and the display interface 115 to the operation angle θ2.

In the present embodiment, the display rotation driver 122 is disposed on the cabin body 110, coupled to the display 115 and electrically connected to the micro control unit 142 of the control module 140, and configured to receive the display rotation command S2 to rotate the display 115 and face the seat back 112 and the user. The display interface sliding driver 123 is disposed on the cabin body 110, coupled to the display interface 115 and electrically connected to the micro control unit 142 of the control module 140, and configured to receive the display interface sliding command S3 to adjust the height of the display interface 115. For example, when the display interface 115 is adjusted in height, the user's line of sight SI is looking up at two-thirds of the height of the display interface 115.

Referring to fig. 1 and 2, the computer cabin 100 of the present embodiment further includes a reset key 150 electrically connected to the micro control unit 142 of the control module 140 and configured to provide a reset signal R. The micro control unit 142 of the control module 140 is configured to receive the reset signal R and send a reset instruction RS. The driving module 120 is configured to receive the reset instruction RS to drive the cabin body 110 to return to the preset state.

The configuration of the computer cabin 100 of the present embodiment has been described above. The computer cabin adjusting method of the present embodiment is described below. Fig. 4 is a flowchart of a computer cabin adjusting method according to an embodiment of the invention. Referring to fig. 1, 2 and 4, the cabin adjusting method of the present embodiment includes the following steps: the sensing data D is provided by the sensing module 130, wherein the sensing data D includes a seat pressure sensing value D1 and a back pressure sensing value D2. In step S220: the determination is made by the control module 140, including determining whether the sensed data D exceeds a preset value. In step S230: the control module 140 sends an adjustment command S, wherein the control module 140 sends the adjustment command S when the control module 140 determines that the sensed data D exceeds the preset value. In step S240: the driving module 120 receives the adjustment command S to synchronously rotate the seat 111, the backrest 112, and the display interface 115 from a predetermined angle (default angle) to a working angle θ2.

FIG. 5 is a block diagram of a computer cabin adjusting method according to an embodiment of the invention. Referring to fig. 5, in the computer cabin adjusting method of the present invention, the determining process performed by the micro control unit 142 of the control module 140 includes receiving the sensing data D. Then, it is further determined whether the sensing data D exceeds a preset value. Finally, after the micro control unit 142 of the control module 140 determines that the sensing data D exceeds the preset value, the micro control unit 142 sends the adjustment command S.

In an embodiment of the present invention, providing the sensing data D through the sensing module 130 (step S210) includes: the seat pressure sensor 131 senses the pressure applied to the seat 111 and correspondingly generates a seat pressure sensing value D1; and sensing the pressure experienced by the seat back 112 by the seat back pressure sensor 132 and correspondingly generating a seat back pressure sensing value D2. The determination (step S220) by the control module 140 includes: judging whether the seat pressure sensing value D1 and the back pressure sensing value D2 in the sensing data D exceed preset values or not. That is, since the user sits on the seat 111 and leans against the backrest 112, the control module 140 determines whether the seat pressure sensing value D1 and the backrest pressure sensing value D2 exceed the preset values, so as to indirectly know whether the user sits on the seat 111 and leans against the backrest 112 (i.e. whether the user sits on the seat), and adjust the seat 111, the backrest 112 and the display interface 115 to the working angle after the user sits on the seat.

Referring to fig. 1, 2, 4 and 5, in an embodiment of the invention, providing the sensing data D by the sensing module 130 (step S210) further includes: the pressure received by the headrest 113 of the cabin body 110 is sensed by the headrest pressure sensor 133 and a headrest pressure sensing value D3 is generated accordingly. The determination (step S220) by the control module 140 includes: judging whether the seat pressure sensing value D1, the back pressure sensing value D2 and the headrest pressure sensing value D3 in the sensing data D exceed preset values or not. That is, since the user sits on the seat 111 and leans against the backrest 112 and the headrest 113, the control module 140 determines whether the seat pressure sensing value D1, the backrest pressure sensing value D2 and the headrest pressure sensing value D3 exceed the preset values, so as to indirectly determine whether the user sits on the seat 111 and leans against the backrest 112 and the headrest 113 (i.e. whether the user sits on the seat), and adjust the seat 111, the backrest 112 and the display interface 115 to the working angle after the user sits on the seat.

In an embodiment of the present invention, providing the sensing data D through the sensing module 130 (step S210) further includes: sensing whether the user is positioned above the seat 111 by the human infrared sensor 134 and correspondingly generating a human position sensing value D4; and whether the head of the user is positioned in front of the headrest 113 is sensed by the head infrared sensor 135 and a head position sensing value D5 is correspondingly generated. The determination (step S220) by the control module 140 includes: judging whether the seat pressure sensing value D1, the seat back pressure sensing value D2, the headrest pressure sensing value D3, the human body position sensing value D4 and the head position sensing value D5 in the sensing data D exceed preset values or not. That is, since the user sits on the seat 111 and leans against the backrest 112 and the headrest 113, and generates a larger value when the user sits on the seat 111 and the head is in front of the headrest 113, the control module 140 determines whether the seat pressure sensing value D1, the backrest pressure sensing value D2, the headrest pressure sensing value D3, the human body position sensing value D4 and the head position sensing value D5 exceed the preset values, so that it can indirectly know whether the user sits on the seat 111 and leans against the backrest 112 and the headrest 113 (i.e. whether the user sits in the computer cabin 100), and whether the user sits in the computer cabin 100, and adjusts the seat 111, the backrest 112 and the display interface 115 to the working angle after the user sits in the sitting position.

Referring to fig. 1, 2, 4 and 5, in an embodiment of the present invention, the determining (step S220) by the control module 140 further includes: it is determined whether the human body position sensing value D4 in the sensing data D exceeds a preset value. The sending of the adjustment instruction S (step S230) by the control module 140 includes: the display interface rotation command S2 is sent by the control module 140, wherein when the control module 140 determines that the human body position sensing value D4 in the sensing data D exceeds the preset value, the control module 140 sends the display interface rotation command S2. Receiving the adjustment instruction S (step S240) by the driving module 120 includes: the display interface rotation command S2 is received by the display interface rotation driver 122, so that the display interface 115 rotates along the axis A2 and faces the back 112 and the user. In other words, the ir sensor 134 generates a larger value when the user is located on the seat 111, and the control module 140 determines whether the sensed value D4 exceeds the preset value, so as to indirectly determine whether the user is sitting in the computer cabin 100 (i.e. whether the user is sitting in the computer cabin), and adjust the display interface 115 to face the seat 111 and the user after the user is sitting in the computer cabin. Accordingly, the computer cabin 100 can provide a larger space for a user to get in and out, and the display interface 115 can automatically face the user after the user sits and positions, which is beneficial to improving the convenience of the user using the computer cabin 100.

In an embodiment of the present invention, providing the sensing data D through the sensing module 130 (step S210) includes: the position of the eyes of the user is sensed by the head infrared sensor 135 and an eye position sensing value D6 is correspondingly generated. The determining (step S220) by the control module 140 further includes: the height of the eyes of the user is judged according to the eye position sensing value D6 in the sensing data D. The sending of the adjustment instruction S (step S230) by the control module 140 includes: the display interface sliding instruction S3 is sent by the control module 140, wherein when the control module 140 determines the height of the eyes of the user according to the eye position sensing value D6 in the sensing data D, the control module 140 sends the display interface sliding instruction S3. Receiving the adjustment instruction S (step S240) by the driving module 120 includes: the display interface sliding driver 123 receives the display interface sliding command S3 to slide the display interface 115 along the axial direction AX to adjust the height of the display interface 115, and when the display interface 115 is adjusted in height, the user' S line of sight SI looks at two thirds of the height of the display interface 115. Accordingly, when the user sits in place, the display interface 115 will automatically adjust to a preferred viewing height to be ergonomic and help to enhance the comfort of the user using the computer cabin 100.

Referring to fig. 1, 2, 4 and 5, in an embodiment of the invention, the determining (S220) by the control module 140 includes: it is determined whether there is a reset signal R generated from the reset key 150. The computer cabin adjusting method further comprises the following steps: sending a reset instruction RS through the control module 140, wherein when the control module 140 receives the reset signal R, the control module 140 sends the reset instruction RS; and receiving a reset instruction RS through the driving module 120 to return to the preset position. Accordingly, when the user wants to leave the computer cabin 100, the user only needs to press the reset key 150 to return the computer cabin 100 to the predetermined angle (i.e. the angle shown in fig. 3A), and the display interface 115 is rotated away from the chair back 112 (i.e. the state shown in fig. 1), which is beneficial to improving the convenience of the user in using the computer cabin 100.

Fig. 6A is a schematic side view of a computer cabin according to another embodiment of the invention. Fig. 6B is a schematic top view of the computer cabin of fig. 6A. FIG. 7 is a circuit block diagram of the computer cabin of FIG. 6A. In the computer cabin 300 of the embodiment shown in fig. 6A, 6B and 7, the configuration and the operation of the cabin body 310, the seat 311, the headrest 313, the posture adjustment driver 321, the display interface sliding driver 323, the sensing module 330, the seat pressure sensor 331, the seat back pressure sensor 332, the headrest pressure sensor 333, the human body infrared sensor 334, the head infrared sensor 335, the control module 340, the storage unit 341, the micro control unit 342 and the reset key 350 are similar to those of the cabin body 110, the seat 111, the headrest 113, the posture adjustment driver 121, the display interface sliding driver 123, the sensing module 130, the seat back pressure sensor 131, the seat back pressure sensor 132, the headrest pressure sensor 133, the human body infrared sensor 134, the head infrared sensor 135, the control module 140, the storage unit 141, the micro control unit 142 and the reset key 150 in the computer cabin 100 of the embodiment shown in fig. 1 and 2, and the detailed description will be omitted.

The embodiment shown in fig. 6A, 6B and 7 is different from the embodiment shown in fig. 1 and 2 in that the seat back 312 of the present embodiment is rotatably disposed on the cabin body 310 along the axis A3, and the adjustment command S includes a seat back rotation command S6. The driving module 320 includes a seat back rotation driver 326 disposed on the cabin body 310, coupled to the seat back 312 and electrically connected to the control module 340. The seatback rotation driver 326 includes, but is not limited to, a motor configured to receive seatback rotation instructions S6 to rotate the seatback 312 and the seat 311 and face the display interface 315. Accordingly, the computer cabin 300 can provide a larger space for a user to get in and out, and the chair back 312 and the chair seat 311 can automatically face the user after the user sits and positions, thereby facilitating the convenience of the user to use the computer cabin 300.

In addition, since the computer cabin 300 of the present embodiment adopts the manner of automatically adjusting the back 312 to face the display interface 315, the display interface 315 without rotation requirement can be a curved display with a wider size. Accordingly, the computer cabin 300 of the present embodiment can also promote visual enjoyment of the user.

Fig. 8 is a schematic view of a computer cabin according to yet another embodiment of the invention. Referring to fig. 8, in the computer cabin 400 of the embodiment shown in fig. 8, the configuration and the operation of the cabin body 410, the seat 411 and the backrest 412 are similar to those of the cabin body 110, the seat 111 and the backrest 112 of the computer cabin 100 of the embodiment shown in fig. 1, and will not be repeated herein. The embodiment shown in fig. 8 differs from the embodiment shown in fig. 1 in that the display interface 415 of the present embodiment includes a projection screen 415a. The computer cabin 400 further includes a projector 460 disposed above the cabin body 410, and the projection screen 415a and the projector 460 are respectively located on two opposite sides of the seat 411. Accordingly, since the projection screen 415a can provide a larger size, the computer cabin 400 of the present embodiment is helpful for improving the visual enjoyment of the user.

In summary, in the computer cabin and the adjusting method thereof of the present invention, the sensing module is disposed on the cabin body and configured to provide sensing data. The sensing data comprises a seat pressure sensing value and a back pressure sensing value. The control module is electrically connected with the driving module and the sensing module and is configured to send an adjustment instruction according to the sensing data. The driving module is configured to receive the adjustment instruction to rotate the seat, the seat back and the display interface to the working angle and reduce the difference between the seat back pressure sensing value and the seat back pressure sensing value. Therefore, the angles of the chair seat, the chair back and the display interface can be automatically adjusted to accord with ergonomics, and the comfort of a user using the computer cabin can be improved.

Although the invention has been described with reference to the above embodiments, it should be understood that the invention is not limited thereto, but rather may be modified and practiced by those skilled in the art without departing from the spirit and scope of the present invention.

Claims (14)

1. A computer cockpit, comprising:

the cabin body comprises a seat, a chair back and a display interface, wherein the seat, the chair back and the display interface are movably arranged on the cabin body, and the display interface and the chair back are respectively positioned on two opposite sides of the seat;

the driving module is arranged on the cabin body;

the sensing module is arranged on the cabin body and is configured to provide sensing data, and the sensing data comprises a seat pressure sensing value and a back pressure sensing value; and

the control module is electrically connected with the driving module and the sensing module and is configured to send an adjustment instruction according to the sensing data,

the driving module is configured to receive the adjustment command, to synchronously rotate the seat, the backrest and the display interface to a working angle and reduce a difference between the backrest pressure sensing value and the seat pressure sensing value so as to reduce the difference and approach zero, wherein the seat and the backrest are pivoted to the cabin body by an axis, and when the seat, the backrest and the display interface are positioned at the working angle, the following relations are satisfied:

W2sin(θ1+θ2)L2＝W1cos(θ2)L1；

w1 is the first pressure applied to the seat;

w2 is the second pressure exerted by the chair back;

θ1 is an initial angle of the chair back and the display interface relative to the chair seat;

θ2 is the working angle;

l1 is a first horizontal distance between the stressed position of the first pressure and the axis; and

l2 is a second horizontal distance between the force receiving position of the second pressure and the axis.

2. The computer cabin of claim 1, wherein the sensing module comprises:

the seat pressure sensor is arranged on the seat and electrically connected with the control module, and is configured to sense the pressure born by the seat and correspondingly generate the seat pressure sensing value.

3. The computer cabin of claim 1, wherein the sensing module comprises:

the chair back pressure sensor is arranged on the chair back and is electrically connected with the control module, and is configured to sense the pressure born by the chair back and correspondingly generate the chair back pressure sensing value.

4. The computer cabin of claim 1, wherein the cabin body further comprises a headrest connected to the seatback, the sensed data further comprises a headrest pressure sensing value, the sensing module comprising:

the headrest pressure sensor is arranged on the headrest and electrically connected with the control module, and is configured to sense the pressure born by the headrest and correspondingly generate the headrest pressure sensing value.

5. The computer cabin of claim 1, wherein the sensed data further comprises a human position sensed value, the sensing module comprising:

the human body infrared sensor is arranged on the cabin body, is electrically connected with the control module, and is configured to sense whether a user is positioned above the seat and correspondingly generate the human body position sensing value.

6. The computer cabin of claim 1, wherein the cabin body further comprises a headrest connected to the seatback, the sensed data further comprises a head position sensing value and/or an eye position sensing value, the sensing module comprising:

the head infrared sensor is arranged on the cabin body and electrically connected with the control module, and is configured to sense whether the head of a user is positioned in front of the headrest and correspondingly generate the head position sensing value, and/or is configured to sense the position of eyes of the user and correspondingly generate the eye position sensing value.

7. The computer cabin of claim 1, wherein the adjustment instructions comprise work angle adjustment instructions, the drive module comprising:

the gesture adjusting driver is arranged on the cabin body, coupled with the seat and the chair back, electrically connected with the control module, and configured to receive the working angle adjusting instruction so as to synchronously rotate the seat, the chair back and the display interface to the working angle.

8. The computer cabin of claim 1, wherein the control module comprises:

a storage unit configured to store a lookup table; and

the micro control unit is electrically connected with the driving module, the sensing module and the storage unit and is configured to send the adjustment instruction according to the sensing data and the comparison table.

9. The computer cabin of claim 8, wherein the seatback and the display interface are rotatably coupled to the seat, the seatback and the display interface have an initial angle relative to the seat, and the lookup table includes the difference value, the initial angle, and the working angle corresponding to the difference value and the initial angle.

10. The computer cabin of claim 1, wherein the display interface is rotatably disposed on the cabin body, the adjustment instructions comprise display interface rotation instructions, and the drive module comprises:

the display interface rotation driver is arranged on the cabin body, is coupled to the display interface, is electrically connected to the control module, and is configured to receive the display interface rotation instruction so as to enable the display interface to rotate and face the chair back.

11. The computer cabin of claim 1, wherein the display interface is slidably disposed on the cabin body, the adjustment instructions comprise display interface sliding instructions, and the drive module comprises:

the display interface sliding driver is arranged on the cabin body, is coupled to the display interface, is electrically connected to the control module, and is configured to receive the display interface sliding instruction so as to adjust the height of the display interface.

12. The computer cabin of claim 1, wherein the seat back is rotatably disposed on the cabin body, the adjustment instructions comprise seat back rotation instructions, and the drive module comprises:

the seat back rotating driver is arranged on the cabin body, coupled with the seat back, electrically connected with the control module and configured to receive the seat back rotating instruction so as to enable the seat back and the seat to rotate and face the display interface.

13. The computer pod of claim 1, wherein the display interface comprises a projection screen, the computer pod further comprising:

the projector is arranged above the cabin body, and the projection cloth curtain and the projector are respectively positioned on two opposite sides of the seat.

14. A computer cabin adjusting method for adjusting the computer cabin according to claim 1, the computer cabin adjusting method comprising:

providing the sensing data by the sensing module, wherein the sensing data comprises the seat pressure sensing value and the back pressure sensing value;

judging by the control module, including judging whether the sensed data exceeds a preset value;

the control module sends the adjustment instruction, wherein when the control module judges that the sensing data exceeds a preset value, the control module sends the adjustment instruction; and

and receiving the adjustment instruction through the driving module and adjusting the adjustment instruction so as to enable the chair seat, the chair back and the display interface to synchronously rotate from a preset angle to the working angle.