FEEDBACK MECHANISM FOR BIOLOGICAL SAFETY CABINET

Abstract

The present invention relates to a feedback mechanism for a biological safety cabinet comprising a glass window and a cover plate in front of the glass window, the feedback mechanism comprises a monitor control component comprising a roller element being fixedly disposed with respect to the cover plate and comprising a rollable roller, and a contact component being fixedly disposed relative to the glass window so that the contact component can move relative to the roller with movement of the glass window, the contact component comprising a recess for receiving the roller, wherein the contact component moves with the glass window to a position corresponding to the roller when the glass window moves relative to the cover plate, such that the roller rolls into the recess, allowing the feedback mechanism to generate tactile feedback.

Claims

1. A feedback mechanism for a biological safety cabinet, the biological safety cabinet comprising a movable glass window and a cover plate disposed in front of at least a portion of the glass window, the feedback mechanism comprising: a monitor control component comprising a roller element being fixedly disposed with respect to the cover plate and comprising a rollable roller; and a contact component being fixedly disposed relative to the glass window so that the contact component can move relative to the roller with movement of the glass window, the contact component comprising a recess for receiving the roller, wherein the contact component moves with the glass window to a position corresponding to the roller when the glass window moves relative to the cover plate, such that the roller rolls into the recess, allowing the feedback mechanism to generate tactile feedback.

2. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the monitor control component further comprises at least a first micro switch and a second micro switch fixedly disposed with respect to the cover plate and configured to contact the contact component when the roller rolls into the recess, thereby generating a first trigger signal and a second trigger signal being used to provide feedback of a position of the roller with respect to the recess.

3. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the roller element of the monitor control component is disposed on a side of the cover plate and the contact component is correspondingly disposed on a side of the glass window.

4. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the roller element of the monitor control component is disposed on a surface of the cover plate facing the glass window, and the contact component is provided on a surface of the glass window facing the cover plate.

5. The feedback mechanism for the biological safety cabinet according to claim 2, wherein the monitor control component comprises a frame to which the roller element and the first micro switch and second micro switch are fixed.

6. The feedback mechanism for the biological safety cabinet according to claim 2, wherein the first micro switch and second micro switch are located on upper and lower sides of the roller element along a direction of movement of the glass window with respect to the cover plate.

7. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the roller element is a spring-driven roller element further comprising a roller bearing portion and a spring disposed within the roller bearing portion.

8. The feedback mechanism for the biological safety cabinet according to claim 7, wherein the spring-driven roller element further comprises a nut configured to rotatably adjust the spring to change a strength of the tactile feedback.

9. The feedback mechanism for the biological safety cabinet according to claim 5, wherein the recess of the contact component is centrally positioned in a middle of the contact component, and wherein the roller element is centrally disposed on the middle portion of the frame.

10. The feedback mechanism for the biological safety cabinet according to claim 2, wherein the first micro switch and the second micro switch each comprises a movable arm, and the first micro switch and the second micro switch contacting the contact component comprises the movable arms of the first micro switch and the second micro switch being pressed by the contact component to generate the first trigger signal and the second trigger signal.

11. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the contact component comprises a top surface and a bottom surface opposite to the top surface, the recess being recessed from the top surface to form opposite side inclined surfaces, and each of the side inclined surfaces comprising a first inclined surface close to the top surface and a second inclined surface continuous with the first inclined surface and close to the bottom surface, and wherein a first inclination angle of the first inclined surface relative to the bottom surface of the contact component is smaller than a second inclination angle of the second inclined surface relative to the bottom surface of the contact component.

12. The feedback mechanism for the biological safety cabinet according to claim 11, wherein the first inclination angle is greater than or equal to 15° and less than 35°, and the second inclination angle is greater than or equal to 35° and less than 45°.

13. The feedback mechanism for the biological safety cabinet according to claim 11, wherein an intersection of the first inclined surface and the second inclined surface is at a substantially middle position of the side inclined surface.

14. The feedback mechanism for the biological safety cabinet according to claim 1, wherein the contact component further comprises edge inclined surfaces angled with a bottom surface of the contact component along a direction of movement of the contact component, and a third inclination angle of the edge inclined surfaces relative to the bottom surface of the contact component is 10° to 30°.

15. A biological safety cabinet comprising the feedback mechanism for the biological safety cabinet according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] With reference to the above objectives, the technical features of the present invention are clearly described in the following claims, and its advantages are apparent from the following detailed description with reference to the accompanying drawings illustrating preferred embodiments of the present invention by way of example without limiting the scope of the present invention concept.

[0026] FIG. 1 shows a perspective view of a biological safety cabinet;

[0027] FIG. 2 shows a view of a part of a biological safety cabinet with a feedback mechanism in accordance with an embodiment of the present invention;

[0028] FIG. 3 shows a schematic of a monitor control component of a feedback mechanism in accordance with an embodiment of the present invention;

[0029] FIG. 4 shows a schematic of the roller element of the monitor control component of FIG. 3;

[0030] FIG. 5 shows a schematic of a contact component of a feedback mechanism in accordance with an embodiment of the present invention;

[0031] FIG. 6 shows a schematic of a contact component of a feedback mechanism in accordance with another embodiment of the present invention;

[0032] FIG. 7 shows a schematic of a monitor control component of a feedback mechanism in accordance with a further embodiment of the present invention;

[0033] FIG. 8 shows a perspective view of the position of the feedback mechanism in accordance with a further embodiment of the present invention when the glass window of the biological safety cabinet does not reach the working position; and

[0034] FIG. 9 shows a perspective view of the position of the feedback mechanism in accordance with a further embodiment of the present invention when the glass window of the biological safety cabinet reaches the working position.

DETAILED DESCRIPTION OF THE INVENTION

[0035] The following embodiments of the present invention are described in detail with reference to the accompanying drawings, so as to more clearly understand the purpose, features and advantages of the present invention. It should be understood that the embodiments shown in the drawings are not intended to limit the scope of the present invention, but only to illustrate the essential spirit of the technical solution of the present invention.

[0036] Herein, the described direction is defined according to the user's position at work, where “front” refers to the direction in which the user faces the user during work; “upper” refers to the upward direction when the user is working; and “lower” refers to the downward direction when the user is working.

[0037] The term “tactile feedback” as used herein refers to the mechanical stimulation of the force transmitted to the user by touching the feedback mechanism or a portion to which the feedback mechanism is attached when the user uses the feedback mechanism of the present invention. Through this mechanical stimulation, the user can know whether the glass window has reached the working position.

[0038] The term “digital feedback” as used herein refers to the electronic signal displayed on the human-machine interface due to the triggering of electronic components, herein the triggering of a micro switch when the user uses the feedback mechanism of the present invention. Herein, digital feedback is characterized as a digital signal that displays “1” on the human-machine interface. The user can use this digital signal to determine whether the glass window has reached the working position.

[0039] For ease of illustration, in the following description, the same or similar components use the same reference number. It should be understood that “first” and “second” in the description can be interchanged without affecting the description of the embodiments.

[0040] FIGS. 1 and 2 show a view of a biological safety cabinet 1 mounted with a feedback mechanism according to the present invention. The biological safety cabinet 1 comprises a movable glass window 2 and a cover plate 3 located on the front of at least a part of the glass window 2. The decorative bar of the cover plate is removed in FIG. 2. As shown, the biological safety cabinet is equipped with a feedback mechanism 10, and the feedback mechanism comprises a monitor control component and a contact component. Hereinafter, the monitor control component and the contact component of the embodiment of the present invention will be described in detail with reference to FIGS. 3-5.

[0041] FIG. 3 shows in detail the monitor control component 100 of the feedback mechanism according to an embodiment of the present invention. The monitor control component comprises a roller element 110 and optionally a frame 130. The roller element 110 can be fixedly disposed relative to the cover plate 3, preferably on the side of the cover plate 3; alternatively, the roller element 110 can be fixed on the frame 130, and the frame 130 can be fixed relative to the cover plate 3 for example by screw connection.

[0042] Referring to FIG. 4, the roller element 110 comprises a rollable roller 111 and a roller bearing portion 112, and the roller element 110 is positioned such that the roller 111 thereof faces the glass window 2 from the cover 3. Further, the roller element 110 further comprises a spring (not shown) disposed in the roller bearing portion 112 and connected to the roller 111, so that when the roller 111 is under pressure (for example, as described below, the pressure generated by contact with a contact component), the spring is compressed, and when the pressure of the roller 111 disappears, the spring is released, thereby allowing the roller 111 to roll on a non-planar surface.

[0043] The above spring-driven roller element 110 further comprises a nut 113 configured to rotatably adjust the spring to change the strength of the tactile feedback.

[0044] FIG. 5 shows a contact component 200 according to the feedback mechanism 10, which is fixedly disposed with respect to the glass window 2, preferably on one side of the glass window, so that the contact component 200 can move along with the movement of the glass window 2, thereby moving with respect to the roller 111 of the roller element 110 of the monitor control component 100.

[0045] Referring to FIG. 2, it should be noted that although the roller element of the monitor control component is preferably disposed on one side of the cover plate, and correspondingly, the contact component is disposed on one side of the glass window, so that the contact component can move relative to the roller, those skilled in the art can adopt other methods to achieve this goal, for example by disposing the roller element of the monitor control component on a surface of the cover plate facing the glass window, and disposing the contact component on a surface of the glass window facing the cover plate.

[0046] Referring back to FIG. 5, the contact component 200 comprises a top surface 201 and a bottom surface 202 opposite to the top surface 201 and formed with raised portions 210 for applying pressure to the roller 111 and a recess 220 for receiving the roller. The shape of the raised portions 210 and the recess 220 are designed together as two isosceles trapezoids. Particularly, as shown, the raised portions 210 have edge inclined surfaces 211 angled with respect to the bottom surface 202 of the contact component 200, the top surface 201 (i.e., the top surface 201 of the contact component 200), and side inclined surfaces 230 angled with respect to the bottom surface 202 along the direction of movement of the contact component 200, and the recess is defined by the inclined side 230. When the user pushes the glass window up or pulls the glass window from down, the raised portions 210 and the recess 220 are allowed to contact the roller one after another, but this is only an example, and other suitable shapes of the contact component can be adopted, as long as the roller 111 passes the raised portion and enters the recess when the glass window reaches the working position. In addition, in the present invention, the recess 220 of the contact component 200 is centrally positioned in the middle of the contact component 200, and wherein the roller element 110 is correspondingly centrally disposed on the middle portion of the frame 130, but this is also by way of example and not by limitation.

[0047] When the glass window 2 of the biological safety cabinet 1 does not enter the working position, the contact component 200 does not contact the roller 111 of the roller element 110 of the monitor control component 100.

[0048] When the user is pushing or pulling the glass window 2 to move the glass window relative to the cover plate 3, the glass window 2 moves to a position corresponding to the roller 111, so that the roller 111 first follows the raised portion 210 of the contact component 200 and receives pressure from the raised portion 210, thereby compressing the spring, and the frictional force increases accordingly.

[0049] When the glass window 2 of the biological safety cabinet 1 enters the working position, the roller 111 rolls into the recess 220 and releases the pressure, resulting in a sudden reduction in friction, so that the tactile feedback generated by the feedback mechanism reminds the user that the glass window 2 has reached the working position.

[0050] Tactile feedback has been achieved through the feedback mechanism 10 comprising the monitor control component 100 and the contact component 200 with a recess as. However, in the actual verification process, it was found that the roller of the monitor control component 100 would get stuck in the groove of the slider, causing the glass window to be unable to move out of the working position. By adjusting the intensity of the tactile mechanism, although the roller can be removed from the recess of the contact component, the tactile sensation of the glass window will become less obvious when it reaches the working position. So the user needs a balance that ensures a clear tactile feedback when the user moves the glass window to the working position, but also the ability to move the window out of the working position easily.

[0051] According to another embodiment of the invention, the feedback mechanism comprises a monitor control component 100 and a multi-angle contact component 300. Similar to the monitor control component shown in FIG. 3, the monitor control component 100 comprises a roller element 110 and optionally a frame 130, so that the relevant similar components are not described, and the contact component 300 is described in detail below.

[0052] FIG. 7 shows a plan view of such a multi-angle contact component 300. The contact component 300 has a top surface 301 and a bottom surface 302 opposite to the top surface 301, an edge inclined surface 311 angled at an angle C with respect to the bottom surface 302 of the contact component 300 along the direction of movement of the contact component 300, and a recess 320 which is recessed from the top surface 301 to form opposite side inclined surfaces 330, each of the side inclined surfaces comprising a first inclined surface 331 near the top surface 301 and a second inclined surface 332 continuous with the first inclined surface 331 and close to the bottom surface, and the roller 111 rolls into and out of the recess 320 along the first inclined surface 331 and the second inclined surface 332.

[0053] In this embodiment, an inclination angle A of the first inclined surface 331 with respect to the bottom surface 302 of the contact component 300 is smaller than an inclination angle B of the second inclined surface 332 with respect to the bottom surface 302, so that the different angles of the inclined surfaces can be used to facilitate moving the glass window while maintaining a distinct tactile feedback. Preferably, the inclination angle A of the first inclined surface 331 satisfies 15°≤A<35°, and the inclination angle B of the second inclined surface 332 satisfies 35°≤B<45°. Further preferably, the inclination angle C of the edge inclined surface 211 with respect to the bottom surface 302 satisfies 10°≤C≤30°.

[0054] The preferred inclination angle can be briefly illustrated by referring to the following tests.

[0055] In the recess 220 (see FIG. 5), the inclination angle of the side inclined surface in relation to the tension force is shown in Table 1.

TABLE-US-00001 TABLE 1 Not touching 45° the top top Maximum change item status surface 30° surface 45° force force 1 Push 69N 91N 70N 115N 115N  46N pull 41N 76N 42N 190N 190N 149N

[0056] It can be found that when the angle is at 45°, the force value reaches 190 N when pulling the glass, while according to Table 1-10-14 of the mechanical design manual, the approximate value of the static force when the forearm is bent is 150 N. Therefore, this can result in not being able to pull the glass.

[0057] On the other hand, in the recess 320 (see FIG. 6), with angle A=30°, angle B=40°, and angle C=20°, for example, the relationship between the inclination angle A of the inclined surface 221 and the tension force is shown in Table 2.

TABLE-US-00002 TABLE 2 Not touching 45° the top C = top B = A = Maximum change item status surface 20° surface 45° 30° force force 1 Push 68.5N .sup. 85N .sup. 73N 95N .sup. 94N 95N 26.5N pull .sup. 41N .sup. 67N .sup. 50N 88N 87.8N 88N .sup. 47N 2 Push 64.7N 84.4N .sup. 67N 100.4N   97.5N 100.4N   35.7N pull .sup. 39N 67.5N 44.2N 90.7N.sup.  .sup. 90N 90.7N.sup.  51.7N 3 Push 66.6N 82.1N 71.6N 94.3N.sup.  93.5N 94.3N.sup.  27.7N pull 37.8N .sup. 70N .sup. 47N 90N .sup. 89N 90N 52.2N 4 Push  6/N 78.6N 70.8N 94.8N.sup.  94.8N 94.8N.sup.  26.8N pull 38.8N .sup. 73N 52.3N 91N 90.5N 91N 52.2N

[0058] Analysis of the above four groups of data can be obtained that the maximum value of each group of data are not more than 150 N, so the glass window is able to be pulled at this time.

[0059] On the other hand, tactile sensation is generated by force changes in different stages. The 40° Angle position of the recess of the contact component is expected to generate the obvious tactile feedback to the users. It can be seen from the data in the table that the force value changes the most at this point. And the amount of change is relatively larger, then the tactile feeling is more obvious to users.

[0060] With continued reference to FIG. 6, in this embodiment, the intersection of the first inclined surface 331 and the second inclined surface 332 is located at a substantially middle position of the side inclined surface 330. The middle position is the midpoint of the travel when the rollers move on the side inclined surface 330. That is, the first inclined surface 331 and the second inclined surface 332 have equal lengths. Further, the substantially middle position means that the length difference between the first inclined surface 331 and the second inclined surface 332 is ±10%. This design allows both the first inclined surface 331 and the second inclined surface 332 to have a certain length that adequately serves to both make the glass window move smoothly and maintain a distinct tactile feedback. It will be appreciated that the first inclined surface 331 and the second inclined surface 332 may have other lengths such that the intersection of the first inclined surface 331 and the second inclined surface 332 is at other locations.

[0061] It should be understood that although in this embodiment, the side inclined surfaces 330 of the recess 320 of the contact component 300 is shown as having a first inclined surface 331 and a second inclined surface 332, in other embodiments, the recess of the contact component may have three or more inclined surfaces, and in additional embodiments, the concave portion may have a curved surface to improve movement of the glass and to ensure tactile feedback.

[0062] As shown in FIG. 7, according to another embodiment of the present invention, the feedback mechanism comprises a monitor control component 100 and a contact component 200. Similar to that shown in FIG. 3, the monitor control component 100 comprises a roller element 110 and an optional frame 130. Related similar components are not described in detail below.

[0063] As shown, the monitor control component 100 further comprises at least a first micro switch 120a and a second micro switch 120b fixedly disposed with respect to the cover plate 3 and respectively located on upper and lower sides of the roller element along the moving direction of the glass window relative to the cover plate 3, and spaced apart from each other by a distance of the recess 220 of the contact component 200.

[0064] The first micro switch 120a and the second micro switch 120b are configured to contact the contact component when the roller rolls into the recess, thereby generating a first trigger signal and a second trigger signal. Particularly, the first micro switch 120a and the second micro switch 120b respectively include movable arms 121a and 121b. When the roller 111 rolls into the recess 220, those movable arms are in contact with the contact component 200, thereby being pressed to generate the first trigger signal and the second trigger signal for feedback of the position of the roller relative to the recess. Those trigger signals are digital feedback, which can be fed back to the user via the human-machine interface 4 (FIG. 1). For example, the micro switches 120a and 120b can be connected to the human-machine interface 4 via wires, so that the user can see the digital feedback of the micro switches from the human-machine interface 4.

[0065] Similarly, optionally the roller element 110 and the first and second micro switch 120a and 120b are respectively fixedly disposed with respect to the cover plate 3; or the monitor control component comprises a frame 130, so that the roller element 110 and the first and second micro switch 120a and 120b are fixed on the frame 130, and the frame 130 is fixedly disposed with respect to the cover plate 3.

[0066] FIGS. 8 and 9 respectively show a perspective view of the relative position of the monitor control component 100 and the contact component 200 of the feedback mechanism 10 when the glass window of the biological safety cabinet does not enter the working position and when it enters the working position according to another embodiment of the present invention. As shown in FIG. 8, when the user is moving the glass window 2 toward the working position, the contact component 200 moves with the glass window 2 to a position corresponding to the roller 111, so that the roller 111 first follows the raised portion 210 of the contact component 200 and receives pressure from the raised portion 210, and the friction force increases accordingly. Note that the arm of the first micro switch 120a or the arm of the second micro switch 120b may have contacted the protrusion 210 before the roller 111, and is pressed, thereby generating a trigger signal, but at this time the other one of the switches 120a and 120b does not generate a trigger signal, so the user can determine that the glass window has not reached the working position.

[0067] As shown in FIG. 9, when the glass window 2 enters the working position, the roller 111 rolls into the recess 220 and releases the pressure, causing a sudden reduction in friction and thus generating tactile feedback. At the same time, both the first micro switch 120a and the second micro switch 120b contact the raised portions, and both generate digital feedback, so that the user can determine that the glass window 2 has reached the working position by both tactile feedback and digital feedback generated by the feedback mechanism.

[0068] Although the structure of the present invention is illustrated above in conjunction with preferred embodiments, it should be recognized by those of ordinary skill in the art that the above examples are for illustrative purposes only and are not to be taken as a limitation of the present invention. Accordingly, modifications and variations of the present invention may be made, and these modifications and variations will fall within the scope defined by the claims appended to this application.