TW201914949A - Method of manufacturing multi - type gas detector using microelectromechanical systems - Google Patents

Abstract

A method of manufacturing multi-type gas detector by using microelectromechanical systems, including the following steps: providing a microelectromechanical system wafer with a plurality of detection modules, in which the detection modules each contain a plurality of units, and the units each contain a recess; forming a gas-sensing material layer on the microelectromechanical system, and different units of the gas-sensing material layer have different gas sensing material formed thereon; bonding a structural strengthening layer to the microelectromechanical system wafer by anodic bonding, and the structural strengthening layer covers the recess; providing a tape on the structural strengthening layer, and then cutting out to form a plurality of multiple types of gas detection units and bonding these gas detection units to a substrate to obtain the multi-type gas detector. Therefore, structural strength of the gas detector can be improved and broken edges of the microelectromechanical system wafer can be avoid as well by the structural strengthening layer, thereby improving overall yield and reducing costs.

Description

Method for manufacturing various gas detectors by using microelectromechanical process

The invention relates to a gas detector, in particular to a method for manufacturing various gas detectors by using a microelectromechanical process.

Gas detectors are gradually appearing in environmental protection, home quality monitoring, medical and wearable electronic products or smart phones. Considering the need for miniaturization and functional integration, MEMS technology is used to manufacture gas detectors. It is a trend.

A gas detector manufactured by the MEMS technology, such as the gas sensor with a diffusion microcavity and a method for fabricating the same, including: a sensing unit and a a microcavity unit, the sensing unit includes a sensing substrate, the sensing substrate has an upper surface and a lower surface, the upper surface is provided with a first sensing electrode, and the lower surface is provided with a second sensing An electrode, wherein the sensing substrate is embedded with a plurality of conductive electrodes and a plurality of heaters, the conductive electrodes are connected to the heater, the microcavity unit is fixed above the sensing unit, and the microcavity is A microcavity is formed between the unit and the sensing substrate, and a diffusion hole is formed on the microcavity unit.

If a sensing module having a plurality of types of gas sensors is to be manufactured by a micro-electromechanical process, the steps of manufacturing a single type of gas sensor are repeated or independently, and are integrated on a single substrate, not only Increasing the manufacturing cost and lengthening the process time; further, in the case of conventional gas sensors, there will be a groove design, however, the structure of the groove will reduce the strength of the overall component, and during subsequent processing It is easy to cause chipping during cutting, or it may cause accumulation of residue or cleaning liquid generated by cutting in the groove, resulting in a decrease in yield and an increase in cost. Therefore, how to solve the above problems is a subject that the relevant industry has worked together.

The main object of the present invention is to solve the problem that when a sensing module having a plurality of types of gas sensors is manufactured by a microelectromechanical process, a plurality of single types of gas sensors need to be separately manufactured, resulting in an increase in cost and time.

To achieve the above object, the present invention provides a method for fabricating a plurality of gas detectors using a microelectromechanical process, comprising the steps of: S1: providing a MEMS wafer having a plurality of adjacent one another The detection module each includes a plurality of units, each of the units having a top portion, a side stop portion extending from the top periphery of the top portion, and a front portion and the side stop portion a bottom groove, the side stops of the units are connected to each other; S2: forming a gas sensing material layer on the side of the microelectromechanical system wafer away from the bottom groove, the gas sensing material layer having a plurality of separately formed a gas sensing material different from the unit; S3: bonding a structural strengthening layer to the MEMS wafer by anodic bonding, and the structural strengthening layer covers the bottom grooves; S4: providing a bonding tape to The structural strengthening layer is away from one side of the MEMS wafer; S5: cutting along the connection between the detecting modules, and simultaneously cutting the structural strengthening layer and the bonding tape, Cutting out a plurality of multi-type gas detecting unit; and S6: The multi-type gas detecting means is transmitted through the adhesive tape bonding on a substrate to form a plurality of types of gas detector.

In summary, the present invention has the following features:

1. By forming a plurality of gas sensing materials on different units, a plurality of gas detecting units having a plurality of gas sensing materials can be cut at one time, thereby reducing manufacturing cost and shortening processing time.

Second, by the arrangement of the structural strengthening layer, the overall strength can be improved, and the problem of chipping of the MEMS wafer during cutting can be prevented, and the overall yield can be improved and the cost can be reduced.

Third, the bonding by means of anodic bonding can reduce the damage caused to the MEMS wafer by heating, and the bonding of the structural strengthening layer and the MEMS wafer is high without using a bonding agent. There won't be a problem with tilting.

Fourth, compared with the conventional use of liquid adhesive bonding, the present invention utilizes the adhesive tape to directly bond to the substrate, and there is no problem that the gas detecting unit is tilted due to overflow or uneven coating.

The detailed description and technical content of the present invention will now be described as follows:

Referring to FIG. 1 and FIG. 2A to FIG. 2G, the present invention is a method for manufacturing a plurality of gas detectors 60 using a microelectromechanical process, comprising the following steps:

Step S1: Referring to FIG. 2A, a MEMS wafer 10 is provided. The MEMS wafer 10 has a plurality of adjacent detection modules 10a. Each of the detection modules 10a includes There are a plurality of units 11 respectively having a top portion 111, a side stop portion 112 and a bottom groove 113 extending from the periphery of the top portion 111 and surrounding the top portion 111. The slot 113 and the side stops 112 of the units 11 are connected to each other. In the embodiment, the MEMS wafer 10 is made of germanium, and the bottom slot 113 is made by etching. , but not limited to this.

Step S2: Referring to FIG. 2B, a gas sensing material layer 90 is formed on the side of the MEMS wafer 10 away from the bottom trench 113, and the gas sensing material layer 90 has a plurality of different gas sensing layers. The material 91, the gas sensing materials 91 are respectively formed on the different units 11, and different gases can be sensed. This embodiment is exemplified by four different gas sensing materials 91, but it can also be increased or decreased according to requirements.

Step S3: Referring to FIG. 2C, a structural strengthening layer 20 is bonded to the MEMS wafer 10 by anodic bonding, and the structural strengthening layer 20 covers the bottom grooves 113, and the anodic bonding can be performed. The damage to the MEMS wafer 10 due to heating is alleviated, and the bonding of the structural strengthening layer 20 to the MEMS wafer 10 is high without the use of a bonding agent, and there is no problem of tilting. In addition, the present embodiment performs anodic bonding in a negative pressure environment, so that the air in the bottom tank 113 can be reduced, and heat convection heat transfer and concentrated heat source can be effectively avoided. The material of the structural strengthening layer 20 may be glass, borosilicate glass or a combination thereof, and the like, and the thickness of the structural strengthening layer 20 is between 1 mm (mm) and 0.2 mm (mm). In a preferred embodiment of the present invention, the structural reinforcement layer 20 is made of BF33 glass, and the MEMS wafer 10 is made of germanium.

Step S4: As shown in FIG. 2D, a bonding tape 30 is disposed on the side of the structural reinforcing layer 20 away from the MEMS wafer 10. The bonding tape 30 may be a die-cutting tape (DAF) or a cutting. Dicing tape, but not limited thereto, further comprising a bonding layer 31 adjacent to the structural strengthening layer 20 and a protective layer 32 away from the structural strengthening layer 20, The protective layer 32 is for preventing dust from adhering to the adhesive layer 31 to protect the adhesive layer 31 from stickiness.

Step S5: Referring to FIG. 2E, the cutting is performed along the joints of the detecting modules 10a, and the structural reinforcing layer 20 and the adhesive tape 30 are simultaneously cut, and a plurality of types are cut. The gas detecting unit 40, by the arrangement of the structural reinforcing layer 20, can improve the strength of the overall component, prevent chipping during cutting, improve overall yield and reduce cost. Moreover, since the plurality of gas sensing materials 91 are different on the units 11 of the detecting module 10a, a plurality of gas detecting units 40 having a plurality of gas sensing materials 91 can be cut by cutting once, compared to A single gas sensing material 91 is formed on the monolithic MEMS wafer 10, and a plurality of MEMS wafers 10 need to be fabricated for combination. In this case, only a single wafer can be used to produce a plurality of gas sensing materials 91. The multi-type gas detecting unit 40 can reduce the manufacturing cost and shorten the processing time while reducing the inventory of the wafer.

In the embodiment, the MEMS wafer 10, the structural strengthening layer 20, and the bonding tape 30 are cut by a laser (not shown), and the laser is located on the MEMS 10 Aside from one side of the structural strengthening layer 20. Compared with the conventional processing method, the laser does not generate static electricity and has no cutting force, and the damage of the MEMS wafer 10, the structural strengthening layer 20 and possible residual internal stress can be avoided, and the laser can be The machining is completed in an instant and the heat-affected zone is extremely small, ensuring high-precision machining and reducing the residual internal stress caused by heat. Since the laser processing does not require the provision of coolant, the subsequent cleaning problems and the contamination caused by the consumables can be reduced.

In addition, the adhesive tape 30 can surely adhere to the structural strengthening layer 20 to prevent the plurality of types of gas detecting units 40 from being scattered around after cutting, and the laser transmission system does not cut the adhesive tape 30. The protective layer 32.

Step S6: Finally, as shown in FIG. 2F and FIG. 2G, the plurality of gas detecting units 40 are bonded to a substrate 50 through the adhesive tape 30 to form a plurality of gas detectors 60. Since the units 11 of the detecting module 10a are connected to each other, the bonding precision can be improved by separately bonding the units 11 compared with the conventional one. In this step, the following steps are included:

Step S6A: the plurality of gas detecting units 40 are sucked from one side of the microelectromechanical system wafer 10 by using a suction device 70, and at the same time, a pushing device 80 can be used to push from one side of the adhesive tape 30. The gas detecting unit 11 is disposed to facilitate the suction device 70 to adsorb the gas detecting unit 11 and is displaced corresponding to the substrate 50.

Step S6B: The gas detecting unit 11 is then lowered onto the substrate 50, and the gas detecting unit 11 is adhered to the substrate 50 through the bonding layer 31 of the adhesive tape 30 to form the gas detector. Thereby, there is no problem that the adhesive tape 30 is caused by a general liquid adhesive or the tilt of the MEMS wafer 10.

In summary, the present invention has the following features:

1. By forming different gas sensing materials on the detecting module, different gases can be sensed, and as long as the cutting is performed once, a plurality of gas detecting units having a plurality of gas sensing materials can be cut, and Reduce production costs and process time while reducing wafer inventory.

Second, by the arrangement of the structural strengthening layer, the strength of the overall component can be improved, chipping can be prevented during cutting, the overall yield can be improved, and the cost can be reduced.

Third, the anodic bonding method is used to bond the structural strengthening layer and the MEMS wafer, thereby reducing the damage caused to the MEMS wafer by heating, and the bonding layer is not required to be utilized. MEMS wafer bonding is highly flat and does not have the problem of tilting.

Fourth, by doing anodic bonding in a negative pressure environment, air heat convection heat transfer and concentrated heat source can be effectively avoided.

5. By the setting of the adhesive tape, the problem that the various gas detecting units are scattered around after cutting can be prevented.

Sixth, the use of laser for cutting, replacing the traditional processing method, without the role of cutting force, can avoid the damage of the MEMS wafer, the structural strengthening layer and possible residual internal stress, and the laser has high precision and heat. The affected area is extremely small and no coolant is required, which can reduce subsequent cleaning problems and contamination caused by derived consumables.

The present invention has been described in detail above, but the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the scope of the invention. That is, the equivalent changes and modifications made by the scope of the present application should remain within the scope of the patent of the present invention.

10‧‧‧Microelectromechanical system wafers

10a‧‧‧Detection module

11‧‧‧ unit

111‧‧‧ top

112‧‧‧ Side stop

113‧‧‧ bottom slot

20‧‧‧Structural strengthening layer

30‧‧‧Adhesive tape

31‧‧‧Bonded layer

32‧‧‧Protective layer

40‧‧‧Multiple types of gas detection units

50‧‧‧Substrate

60‧‧‧Multiple types of gas detectors

70‧‧‧Attraction device

80‧‧‧Empty device

90‧‧‧ gas sensing material layer

91‧‧‧Gas sensing materials

S1~S6, S6A, S6B‧‧‧ steps

FIG. 1 is a schematic flow chart of an embodiment of the present invention. 2A-2G are schematic diagrams showing a partial cross-section manufacturing process according to an embodiment of the invention.

Claims (9)

A method for fabricating a plurality of gas detectors using a microelectromechanical process includes the following steps: S1: providing a MEMS wafer having a plurality of adjacent detection modules, The detection modules each include a plurality of units, each of the units having a top portion, a side stop portion extending from the top periphery of the top portion, and a bottom groove formed by the top portion and the side stop portion. The side barriers are connected to each other; S2: forming a gas sensing material layer on the side of the microelectromechanical system wafer away from the bottom trench, the gas sensing material layer having a plurality of gas sensings respectively formed in different units Material: S3: bonding a structural strengthening layer to the MEMS wafer by means of anodic bonding, and the structural strengthening layer covers the bottom grooves; S4: providing a bonding tape to the structural strengthening layer away from the MEMS One side of the system wafer; S5: cutting along the joints of the detection modules, and simultaneously cutting the structural strengthening layer and the bonding tape, and cutting a plurality of kinds of gases Sensing unit; and S6: The multi-type gas detecting means is transmitted through the adhesive tape bonding on a substrate to form a plurality of types of gas detector. The method for manufacturing a plurality of types of gas detectors by using a microelectromechanical process as described in claim 1, wherein the material of the structural strengthening layer is selected from the group consisting of glass, borosilicate glass, and combinations thereof. The method of manufacturing a plurality of types of gas detectors by using a microelectromechanical process according to claim 1, wherein the structural strengthening layer and the MEMS wafer are anodic bonded in a negative pressure environment. The method for manufacturing a plurality of types of gas detectors by using a microelectromechanical process according to claim 1, wherein in step S5, the MEMS wafer, the structural strengthening layer, and the bonding are utilized by a laser. The tape is cut, the laser being located on the side of the MEMS wafer away from the structural reinforcement layer. A method for manufacturing a plurality of types of gas detectors using a microelectromechanical process as described in claim 1, wherein the bonding tape is a die-cutting tape or a dicing tape. A method of fabricating a plurality of types of gas detectors using a microelectromechanical process as described in claim 1, wherein the structural strengthening layer has a thickness of between 1 mm and 0.2 mm. The method for manufacturing a plurality of types of gas detectors by using a microelectromechanical process as described in claim 1, wherein in step S6, the method further comprises the following steps: S6A: using a suction device from the MEMS wafer One of the plurality of gas detecting units is sucked and displaced correspondingly to the substrate; and S6B: the plurality of gas detecting units are adhered to the substrate through the adhesive tape to form the plurality of gas detectors. The method for manufacturing a plurality of types of gas detectors by using a microelectromechanical process as described in claim 7, wherein in step S6A, a plurality of gas detectors are pushed from one side of the adhesive tape by using an ejector device. Measurement unit. The method of manufacturing a plurality of types of gas detectors by using a microelectromechanical process according to claim 1, wherein the bonding tape further comprises a bonding layer adjacent to the structural strengthening layer, and a reinforcing layer away from the structural strengthening layer. Protective layer.