CN112809374A - Key assembling machine - Google Patents

Abstract

The invention discloses a key assembling machine, which is used for assembling keys and comprises: the base station is arranged on the outer side of the rotary table and is provided with a bottom cover feeding portion, a pressing piece mounting portion, an elastic piece mounting portion, a movable contact piece mounting portion, a terminal pin mounting portion, a static contact piece mounting portion, a spring mounting portion and an upper cover mounting portion along the rotating direction of the rotary table. According to the key assembling machine of the present invention, since the turntable is provided on the base and the plurality of parts for automatically assembling the parts of the key are provided outside the turntable, not only can the key be automatically assembled, but also the assembling efficiency is high.

Description

Key assembling machine

Technical Field

The invention relates to the technical field of product assembly, in particular to a key assembly machine.

Background

In the production of various apparatuses, by requiring the use of an assembling machine, for example, among known assembling machines, there are automatic assembling machines for keys of various keyboards such as keys of a telephone set, keys of a keyboard of a computer, keys of a keyboard of a notebook computer, and keys of various game machines such as a slot machine, a clip doll machine, and the like. However, the upgrading of various devices is very fast, and after the upgrading of the devices, there is no assembly standard machine which can be used directly on the market, and in order to achieve the assembly of the products, a lot of manual assembly fixtures are usually designed for assembly, which is very inefficient and cannot meet the requirement of mass production.

Disclosure of Invention

The present invention is directed to solving one of the problems of the prior art. Therefore, the invention provides the key assembling machine which can automatically assemble the keys and has high assembling efficiency.

According to one aspect of the invention, the key assembling machine is used for assembling keys and comprises: the base station is arranged on the outer side of the rotary table and is provided with a bottom cover feeding portion, a pressing piece mounting portion, an elastic piece mounting portion, a movable contact piece mounting portion, a terminal pin mounting portion, a static contact piece mounting portion, a spring mounting portion and an upper cover mounting portion along the rotating direction of the rotary table.

The key assembling machine of one aspect of the invention has at least the following beneficial effects: the rotary table is arranged on the base station, and a plurality of components for automatically assembling parts of the keys are arranged on the outer side of the rotary table, so that the keys can be automatically assembled, and the assembling efficiency is high.

In some embodiments, the lid loading portion comprises: the first material distributing part is provided with a first vibrating disc, and the first vibrating disc is used for discharging the bottom cover;

a first manipulator portion configured to take the bottom cover from the first material dividing portion and fit the bottom cover to the jig when one of the jigs is located at a feeding position of the first manipulator portion.

In some embodiments, the pusher mount includes: the second material dividing part is provided with a second vibrating disc, and the second vibrating disc is used for discharging the pressing piece; a second manipulator portion configured to take the pressing piece from the second material dividing portion and to assemble the pressing piece to the jig when one of the jigs is located at a feeding position of the second manipulator portion.

In some embodiments, the clip mounting portion comprises: a first sheet feeding section configured to continuously feed one end of a first sheet in a roll shape; a first sheet punching section configured to punch one end of the first sheet continuously fed out to form an elastic piece; and the third mechanical hand part is used for obtaining the elastic sheet from the first sheet stamping part and assembling the elastic sheet to the clamp when one of the clamps is positioned at the feeding position of the third mechanical hand part.

In some embodiments, the movable contact mounting part includes: a second sheet feeding unit configured to continuously feed one end of a second sheet in a roll shape; a second sheet punching section configured to punch one end of the second sheet continuously sent out to form a movable contact piece; a fourth manipulator section configured to take the movable contact piece from the second sheet punching section and to fit the movable contact piece to the jig when one of the jigs is located at a feeding position of the fourth manipulator section.

In some embodiments, the terminal pin mounting portion comprises: the third material distributing part is provided with a third vibrating disc, and the third vibrating disc is used for discharging the terminal pins; a fifth manipulator section configured to take the terminal pins from the third dividing section and fit the terminal pins to the jig when one of the jigs is located at a feeding position of the fifth manipulator section.

In some embodiments, the static contact mounting portion comprises: the fourth material distributing part is provided with a fourth vibrating disc, and the fourth vibrating disc is used for discharging the static contact pieces; a sixth manipulator section configured to take the static contact from the fourth dividing section and assemble the static contact to the jig when one of the jigs is located at a feeding position of the sixth manipulator section.

In some embodiments, the spring mount comprises: the fifth material dividing part is provided with a fifth vibrating disk, and the fifth vibrating disk is used for discharging the spring; a seventh manipulator portion configured to obtain the spring from the fifth material dividing portion and to assemble the spring to the jig when one of the jigs is located at a feeding position of the seventh manipulator portion.

In some embodiments, the upper cover mounting part includes: the sixth material distributing part is provided with a sixth vibrating disk, and the sixth vibrating disk is used for discharging the upper cover; an eighth manipulator section configured to obtain the upper cover from the sixth dividing section, and to assemble the upper cover to the jig when one of the jigs is located at a feeding position of the eighth manipulator section.

In some embodiments, the base station is provided with a blanking portion at the outer side of the turntable, and the blanking portion is arranged behind the upper cover mounting portion along the rotation direction of the turntable.

Drawings

Fig. 1 is a perspective view of an embodiment of a key assembling machine of the present invention.

FIG. 2 is a perspective view of one embodiment of a clamp for clamping a key.

Fig. 3 is a partial cross-sectional view of the clamp of fig. 2 at a-a (showing the bypass block of the clamp extended).

Figure 4 is a partial cross-sectional view of the clamp of figure 2 at a-a (showing retraction of the bypass block of the clamp).

Fig. 5 is a schematic view of the bottom cover loading part in fig. 1.

Fig. 6 is a schematic view of the first manipulator section of fig. 5.

Fig. 7 is a schematic view of the pressing lever mounting part in fig. 1.

Fig. 8 is a schematic view of the spring mounting portion of fig. 1.

Fig. 9 is a schematic view of the first sheet punching part and the third manipulator part in fig. 8.

Fig. 10 is a schematic view of the moving contact mounting part in fig. 1.

Fig. 11 is a schematic view of the terminal pin mounting section of fig. 1.

Fig. 12 is a main schematic view of fig. 11.

Fig. 13 is a schematic diagram of the correcting section in fig. 11.

Fig. 14 is a schematic view of the stationary contact mounting part of fig. 1.

Fig. 15 is a schematic view of the spring mounting portion of fig. 1.

Fig. 16 is a schematic view of the upper cover mounting portion of fig. 1.

Fig. 17 is a schematic view of the blanking portion in fig. 1.

Fig. 18 is a schematic diagram of the conduction detecting unit in fig. 1.

Fig. 19 is an exploded view of a key to be mounted on the key mounting machine of the present invention.

Fig. 20 is a schematic view of the bottom cover in fig. 19.

Fig. 21 is a schematic view of the pressing member in fig. 19.

Fig. 22 is a schematic view of the upper cover of fig. 19.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, the meaning of a plurality of means is one or more, the meaning of a plurality of means is two or more, and larger, smaller, larger, etc. are understood as excluding the number, and larger, smaller, inner, etc. are understood as including the number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present invention, unless otherwise explicitly limited, terms such as arrangement, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention in combination with the specific contents of the technical solutions.

In the following description, the same or similar technical features are denoted by the same reference numerals and are distinguished only when necessary.

Fig. 19 is an exploded view of a key 100 as an object to which the key assembly machine is mounted, fig. 20 is a schematic view of a bottom cover 101, fig. 21 is a schematic view of a pusher 102, and fig. 22 is a schematic view of an upper cover 108, and first, the key 100 as an object to which the key assembly machine of the present embodiment is mounted will be described with reference to fig. 19 to 22 before describing the key assembly machine of the present embodiment. The key 100 mounted on the key assembly machine of the present embodiment is, for example, a key of a large specification used in a game machine, and includes a bottom cover 101, a pressing member (may also be called a white dot) 102, a spring piece 103, a movable contact piece 104, a terminal pin 105, a stationary contact piece 106, a spring 107, and an upper cover 108. Wherein, a first mounting groove 109 is provided at a substantially middle position of the inside of the bottom cover 101, and the pressing piece 102 is mounted in the first mounting groove 109. The second mounting groove 110 is formed at the right side of the inside of the bottom cover 101, and the elastic piece 103 is mounted in the second mounting groove 110. A third mounting groove 111 is provided at a position near the first mounting groove 109 on the left side of the inside of the bottom cover 101, and the movable contact 104 is inserted into the third mounting groove 111. Further, one end of the terminal pin 105 is also inserted into the third mounting groove 111 and positioned at the front side of the third mounting groove 111. A fourth mounting groove 112 is provided at a position near the left edge of the bottom cover 101 (i.e., a position more to the left with respect to the third mounting groove 111) at the left side of the inside of the bottom cover 101, and one end of the stationary contact 106 is inserted into the fourth mounting groove 112. The middle of the pressing member 102 is provided with a fifth mounting groove 113, and a mounting post 114 is provided in the fifth mounting groove 113, and the spring 107 is inserted into the mounting post 114. The upper cover 108 covers the upper portion of the bottom cover 101, and a sixth mounting groove 115 and a seventh mounting groove 116 are respectively formed in the left side of the upper cover 108, and the other end of the terminal pin 105 is inserted into the sixth mounting groove 115 and the other end of the stationary contact 106 is inserted into the seventh mounting groove 116.

The order of assembling the push button 100 of the present embodiment is not particularly limited as long as it can meet the requirement of automatic assembly, and for example, the order of assembling the static contact 106 is not related to the installation of the other components except the bottom cover 101, and therefore, the order of installing the static contact 106 can be actually adjusted according to the process. In addition, for example, the installation of the spring plate 103 and the movable contact 104 is not related, so the installation sequence between the spring plate 103 and the movable contact 104 can be actually adjusted according to the process.

Fig. 1 is a perspective view of an embodiment of a key assembly machine, and referring to fig. 1, a key assembly machine according to an aspect of the present invention is used for assembling a key 100, and includes: the base 117 is provided with a base plate 117, a turntable 118 is arranged on the base plate 117, a plurality of clamps 119 for clamping the bottom cover 101 of the key 100 are arranged on the turntable 118, and the base plate 117 is provided with a bottom cover feeding part 120, a pressing rod mounting part 121, an elastic piece mounting part 122, a movable contact piece mounting part 123, a terminal pin mounting part 124, a static contact piece mounting part 125, a spring mounting part 126 and an upper cover mounting part 127 on the outer side of the turntable 118 along the rotating direction of the turntable 118.

In the present embodiment, since the turn table 118 is provided on the base 117 and a plurality of members for automatically assembling parts of the key 100 are provided outside the turn table 118, not only the key 100 can be automatically assembled but also the assembly efficiency is high.

It should be noted that, although the above components are listed for automatically assembling cases, the relative positions of the components are not particularly limited, and those skilled in the art can make appropriate adjustments according to the actual assembling process.

In addition, a precision divider 128 may be mounted on the base 117, and the precision divider 128 may be a commercially available precision divider. The number of equal parts of the precision divider 128 is selected according to the actual workstation, for example, a 12-equal divider can be selected. The precision divider is driven by a motor.

Fig. 2 is a perspective view of a clamp 119 for holding the key 100, and fig. 3 is a partial sectional view of the clamp 119 in fig. 2 at a-a (showing the escape block 134 of the clamp 119 extending). FIG. 4 is a partial cross-sectional view of the clamp 119 of FIG. 2 at A-A (illustrating retraction of the bypass block 134 of the clamp 119). Referring to fig. 2 to 4, the jigs 119 on the base 117 may be selected according to actual stations, and for example, 12 jigs 119 may be uniformly provided on the base 117 in the axial direction. The clamp 119 includes a base 129, a receiving groove 130 is disposed on the base 129 for receiving the bottom cover 101 and positioning the bottom cover 101, a fixing block 131 is disposed on one side of the receiving groove 130, and the fixing block 131 can be driven by the positioning spring 132 to extend into the receiving groove 130 and reliably fix the bottom cover 101 in the receiving groove 130. The base 129 is provided with a first avoidance groove 133 (for good product detection by a pressing cylinder 260 of a conduction detection unit 258 (see fig. 18 for assistance)) below the accommodation groove 130. In addition, an avoiding block 134 is further arranged below the base 129, and a second avoiding groove 135 is formed in the avoiding block 134. One end of the escape block 134 is connected to the switching spring member 136, and when the escape block 134 is not subjected to an external force, the second escape groove 135 and the first escape groove 133 are misaligned, and the escape block 134 blocks the first escape groove 133, so that the pressing member 102 is prevented from falling from the first escape groove 133 after the pressing member 102 is mounted to the bottom cover 101. When the escape block 134 is pushed by an external force, the escape block 134 compresses the switching spring member 136 and slides, and the second escape groove 135 and the first escape groove 133 communicate with each other, and at this time, a pressing rod driven by a pressing cylinder 260 described below can be allowed to pass through the second escape groove 135 and the first escape groove 133 to press the pressing member 102.

The respective components will be described in detail below.

[ bottom cover loading part 120]

Fig. 5 is a schematic view of the bottom cover loading part 120, fig. 6 is a schematic view of the first manipulator 138 in fig. 5, referring to fig. 5 and 6, and with additional reference to fig. 1, in some embodiments, in order to load the bottom cover 101 at a high speed, the bottom cover loading part 120 includes: a first dispensing section 137 and a first robot section 138. The first distributing part 137 has a first vibrating tray 139, and the first vibrating tray 139 is used for discharging the bottom cover 101. The first robot section 138 is configured to take the bottom cover 101 from the first stock section 137 and fit the bottom cover 101 to the jig 119 when one of the jigs 119 is located at a loading position of the first robot section 138 (for convenience of explanation, the loading position of the first robot section 138 is referred to as a bottom cover loading position 140).

Specifically, since the bottom cover 101 is substantially in a regular shape, in the present embodiment, the first vibrating plate 139 is selected to sort and discharge the bottom covers 101, which can greatly improve the efficiency and accuracy of discharging the bottom covers 101.

At the position of the discharge port of the first vibratory pan 139 (for convenience of explanation, the position of the discharge port of the first vibratory pan 139 is referred to as a bottom cover discharge position 141), a first cylinder 142 is provided, a first switching block 143 is connected to the first cylinder 142, and the first switching block 143 is provided with a bottom cover receiving groove 144 which is abutted with the discharge port of the first vibratory pan 139 to obtain the bottom cover 101. When the bottom cover 101 needs to be obtained, the bottom cover accommodating groove 144 is in butt joint with the discharge hole of the first vibrating disk 139, and after the bottom cover 101 is obtained, the first air cylinder 142 drives the first switching block 143 to switch positions so as to block the discharge hole of the first vibrating disk 139.

In addition, a first detection element 145 is provided at the bottom cover discharge position 141. The first detection element 145 is used to detect whether the bottom cover receiving groove 144 has been captured to the bottom cover 101, and the first detection element 145 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

Further, in order to improve the assembling accuracy and prevent assembling errors, a second detecting element 146 is further provided above the bottom cover discharging position 141. The second detecting element 146 is used for detecting whether the discharging direction of the bottom cover 101 is correct. The second detection element 146 may be selected from various sensors capable of outputting different signals according to the distance, such as a photoelectric sensor and an optical fiber sensor, and the second detection element 146 may be selected from a vision system element such as a CCD. Specifically, since the shape of the left side of the inside of the bottom cover 101 (having the third mounting groove 111 and the fourth mounting groove 112) is different from the shape of the right side of the inside of the bottom cover 101 (having the second mounting groove 110), by providing the second detection member 146, the discharge direction of the bottom cover 101 can be confirmed before the bottom cover 101 is loaded, and when the discharge direction of the bottom cover 101 is different from the preset direction, the adjustment is performed by the first robot hand portion 138.

The first robot section 138 includes a first switching drive section 147 capable of switching positions between the bottom cover discharge position 141 and the bottom cover loading position 140, a first rotary drive section 148, and a first jaw 149 for gripping the bottom cover 101, wherein the first rotary drive section 148 is mounted on the first switching drive section 147, and the first jaw 149 is mounted on the first rotary drive section 148. In order to improve the operating efficiency of the first hand unit 138, for example, a commercially available PPU robot may be selected as the first switching drive unit 147, and since the PPU robot has not only switching operation and telescopic operation but also switching operation and telescopic operation at a particularly high frequency, the switching efficiency of the first hand unit 138 can be greatly improved by selecting the PPU robot. To save costs, the first rotary drive part 148 includes a second air cylinder 150 and a first rack and pinion mechanism 151, wherein the second air cylinder 150 is connected with a first rack 152 of the first rack and pinion mechanism 151, and the first holding jaw 149 is connected to a first gear 153 of the first rack and pinion mechanism 151. Therefore, when the second detecting element 146 detects that the discharging direction of the bottom cover 101 is different from the preset direction, the second cylinder 150 drives the first rack 152, so as to drive the first gear 153 to rotate, thereby driving the first clamping jaw 149 clamping the bottom cover 101 to rotate to switch positions. The first jaw 149 and the jaws described below may be selected from, for example, a known pneumatic jaw or an electric jaw.

[ pressing lever attachment part 121]

Fig. 7 is a schematic view of the pressing lever mounting part 121, and referring to fig. 7 with additional reference to fig. 1, in some embodiments, in order to enable high-speed feeding of the pressing piece 102, the pressing lever mounting part 121 includes: a second dispensing part 154 and a second robot part 155. The second distributing portion 154 has a second vibrating tray 156, and the second vibrating tray 156 is used for discharging the pressing member 102. The second manipulator section 155 is configured to take the pressing piece 102 from the second dispensing section 154 and to assemble the pressing piece 102 to the jig 119 when one of the jigs 119 is located at a feeding position (hereinafter, also referred to as a pressing bar feeding position 157) of the second manipulator section 155.

Specifically, since the pressing pieces 102 have substantially regular shapes, in the present embodiment, the second vibration plate 156 is selected to sort and discharge the pressing pieces 102, which can greatly improve the efficiency and accuracy of discharging the pressing pieces 102.

A third detection element 159 is provided at a position of the discharge port of the second vibratory plate 156 (for convenience of explanation, also referred to as a pressing lever discharge position 158). The third detecting element 159 is used to detect whether or not the presser 102 is present at the bottom presser bar discharge position 158, and the third detecting element 159 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

The second robot section 155 includes a second switching drive section 160 capable of switching positions between a pressing bar discharge position 158 and a pressing bar loading position 157, a first up-down drive section 161, and a vacuum suction tool 162 for sucking the pressing tool 102. The second switching drive unit 160 is mounted on the first vertical drive unit 161. The vacuum suction tool 162 is mounted on the second switching drive unit 160, and is driven by the second switching drive unit 160 to switch between the pressing lever discharge position 158 and the pressing lever feed position 157. The second switching drive unit 160 includes a third cylinder 163 and a swinging member 164 driven by the third cylinder 163 to swing. The vacuum suction unit 162 is attached to the swing unit 164, and the vacuum suction unit 162 is provided with a vacuum suction hole (not shown) for sucking the pressing unit 102. The first up-down driving part 161 includes a fourth cylinder 165, and the fourth cylinder 165 drives the second switching driving part 160 and the vacuum suction member 162 to move up and down.

Specifically, in this embodiment, the specific steps are as follows: when the third detection element 159 detects the pressing piece 102 at the pressing bar discharging position 158, the third air cylinder 163 drives the vacuum suction piece 162 to be positioned at the pressing bar discharging position 158, the fourth air cylinder 165 drives the third air cylinder 163 and the vacuum suction piece 162 to descend, and the vacuum suction piece 162 sucks the pressing piece 102 from the pressing bar discharging position 158. After the vacuum suction member 162 is sucked to the pressing member 102, the fourth cylinder 165 drives the third cylinder 163 and the vacuum suction member 162 to ascend. The third cylinder 163 then drives the vacuum suction member 162 to switch to the pressing lever loading position 157. Next, the fourth cylinder 165 drives the vacuum suction member 162 to descend, so that the pressing member 102 is fitted into the first mounting groove 109 of the bottom cover 101 loaded on the jig 119.

Through setting up mainly by cylinder drive's second manipulator portion 155, not only can realize the automatic feeding of pressing member 102 fast, improve the beat of production, can reduce cost moreover.

[ spring mounting part 122]

Fig. 8 is a schematic view of the spring mounting portion 122, fig. 9 is a schematic view of the first sheet punching portion 167 and the third manipulator portion 168 in fig. 8, with reference to fig. 8 and 9 and with additional reference to fig. 1, in some embodiments, in order to enable high-speed and continuous feeding of the spring 103, the spring mounting portion 122 includes: a first sheet feeding section 166, a first sheet punching section 167, and a third hand section 168. The first sheet feeding unit 166 is provided to continuously feed one end of the first sheet 169 in a roll shape. The first sheet punching section 167 is provided to punch one end of the first sheet 169 continuously fed out to form the elastic sheet 103. The third manipulator section 168 is configured to take the spring plate 103 from the first sheet punching section 167 and assemble the spring plate 103 to the jig 119 when one of the jigs 119 is located at a loading position (also referred to herein as a spring plate loading position 176) of the third manipulator section 168.

The first sheet feeding unit 166 is attached to the base 117 by a bracket such as an aluminum material. The first sheet feeding section 66 includes a first motor 170 and a second motor 171. Wherein, the first motor 170 is connected to the first supporting roller 172 and drives the first supporting roller 172 to rotate. The first sheet 169 in a roll shape is supported by the first support roller 172, and the first sheet 169 is continuously fed out as the first support roller 172 is driven by the first motor 170. The second motor 171 is connected to the second support roller 173 and drives the second support roller 173 to rotate. First protective paper (not shown) for protecting the first sheet 169 peeled from the rolled first sheet 169 is wound around the second support roller 173, and the first protective paper is collected while being wound as the second support roller 173 is driven by the second motor 171.

The first sheet 169 fed out from the first sheet feeding section 166 is fed to the first sheet punching section 167. The first sheet punching portion 167 is provided on the base 117. The first sheet punching section 167 includes, for example, a plurality of first punching cylinders 174, and a plurality of first punches 175 are mounted on the first punching cylinders 174. The number and specifications (output force) of the first punching cylinders 174 are determined according to the position and number of the striking plate 103 to be punched, and the like, and are not particularly limited herein. Similarly, the shape of the first punch 175 is determined according to the actual shape of the spring plate 103, and is not particularly limited herein. By providing the first sheet punching portion 167, the feeding of the first sheet 169, the molding of the elastic piece 103, and the feeding of the elastic piece 103 can be performed simultaneously, and not only can the work flow of the third manipulator portion 168 be refined, but also the feeding efficiency of the third manipulator portion 168 can be improved.

The third robot section 168 is used to assemble the dome 103 punched at the first sheet punching section 167 to the dome feeding position 176. The third robot section 168 includes a rotating portion 177 and a clamping portion 178, wherein the rotating portion 177 includes a fifth cylinder 179, a second rack gear mechanism 180 and a second clamping jaw 181, the fifth cylinder 179 is connected to the second rack 182 of the second rack gear mechanism 180, and the second clamping jaw 181 is connected to the second gear 183 of the second rack gear mechanism 180. Thus, the fifth cylinder 179 rotates the second jaw 181 by driving the second rack and pinion mechanism 180. When the second jaw 181 is rotated to a position opposite to the first sheet punching portion 167, the second jaw 181 can grip the elastic piece 103, and after the second jaw 181 grips the elastic piece 103, the fifth cylinder 179 drives the second jaw 181 to rotate, for example, by 90 ° so that the elastic piece 103 is rotated to a direction in which it is assembled.

The gripper 178 includes a third jaw 184 and a clip loading robot 185 that drives the third jaw 184, and the clip loading robot 185 may also select, for example, a PPU robot and drive the third jaw 184 to switch between a position of interfacing with the second jaw 181 and the clip loading position 176. In a state where the second jaw 181 holds the spring sheet 103 and rotates to the direction in which the spring sheet 103 is assembled, the spring sheet feeding robot 185 drives the third jaw 184 and the second jaw 181 to abut against each other, and the third jaw 184 holds the spring sheet 103. In a state where the third jaw 184 is clamped to the spring plate 103, the spring plate loading robot 185 drives the third jaw 184 to be transferred to the spring plate loading position 176 and fits the spring plate 103 to the second mounting groove 110 of the bottom cover 101. In this embodiment, since the third manipulator section 168 includes the rotation section 177 for adjusting the direction of the elastic piece 103 and the clamping section 178 for loading the elastic piece 103, the work flow of the third manipulator section 168 can be refined, and the loading efficiency of the third manipulator section 168 can be further improved.

[ Movable contact mounting part 123]

Fig. 10 is a schematic diagram of the moving contact piece mounting part 123, referring to fig. 10 and with the auxiliary reference to fig. 1, in some embodiments, in order to be able to load the moving contact piece 104 at high speed and continuously, the moving contact piece mounting part 123 includes: a second sheet feeding section 186, a second sheet punching section 187, and a fourth robot section 188. The second sheet feeding unit 186 is configured to continuously feed one end of a second sheet 189 in a roll shape. The second sheet punching part 187 is provided to punch one end of the second sheet 189 which is continuously sent out to form the movable contact 104. The fourth hand portion 188 is provided to take the movable contact piece 104 from the second sheet punching part 187 and to fit the movable contact piece 104 to the jig 119 when one of the jigs 119 is located at the feeding position (also referred to as a movable contact piece feeding position 190) of the fourth hand portion 188.

The second sheet feeding portion 186 is provided with reference to the first sheet feeding portion 166. For example, the second sheet feeding portion 186 is attached to the bracket and positioned above the base 117. Similarly, the second sheet feeding portion 186 includes a third motor 191 and a fourth motor 192. Wherein, the third motor 191 is connected to the third supporting roller 193 and drives the third supporting roller 193 to rotate. The second sheet 189 in a roll shape is supported to the third support roller 193, and the second sheet 189 is continuously fed out as the third support roller 193 is driven by the third motor 191. The fourth motor 192 is connected to the fourth supporting roller 194, and drives the fourth supporting roller 194 to rotate. A second protective paper (not shown) for protecting the second sheet 189 peeled from the rolled second sheet 189 is wound around the fourth supporting roller 194, and is collected while being wound as the fourth supporting roller 194 is driven by the fourth motor 192.

Likewise, the second sheet punched part 187 is also provided with reference to the first sheet punched part 167. For example, the second sheet 189 fed out from the second sheet feeding portion 186 is fed to the second sheet punching portion 187. The second sheet pressed portion 187 is provided on the base 117. The second sheet punching section 187 includes, for example, a plurality of second punching cylinders 195, and a plurality of second punches 196 are mounted on the second punching cylinders 195. The number and specification (output force) of the second punching cylinders 195 are determined according to the position and number of the movable contact piece 104 to be punched, and are not particularly limited herein. Likewise, the shape of the second punch 196 also determines the shape of the second punch 196 according to the actual shape of the movable contact 104, and is not particularly limited herein. By providing the second sheet pressing portion 187, the feeding of the second sheet 189, the molding of the movable contact piece 104, and the feeding of the movable contact piece 104 can be performed simultaneously, and not only the work flow of the fourth hand unit 188 can be refined, but also the feeding efficiency of the fourth hand unit 188 can be improved.

The fourth robot section 188 includes a first rotary robot 197 and a fourth gripper 198, the first rotary robot 197 may be a selectively rotatable PPU robot, and the fourth gripper 198 is mounted on the PPU robot. The first rotary robot 197 drives the fourth jaw 198 to switch between a position abutting against the second sheet punch 187 (i.e., the movable contact outfeed position 199) and the movable contact sheet infeed position 190. Thus, after the fourth jaw 198 grips the movable contact piece 104 from the second sheet punching part 187, the movable contact piece 104 is transferred to the movable contact piece charging position 190, and the movable contact piece 104 is fitted to the third mounting groove 111 of the bottom cover 101.

[ terminal pin mounting part 124]

Fig. 11 is a schematic view of the terminal pin mounting part 124, fig. 12 is a schematic view of a main part of fig. 11, fig. 13 is a schematic view of the rectifying part 211 of fig. 11, and referring to fig. 11 to 13, in some embodiments, in order to enable high-speed and continuous feeding of the terminal pin 105, the terminal pin mounting part 124 includes: a third dispensing part 200 and a fifth manipulator part 201. The third separating portion 200 has a third vibration plate 202, and the third vibration plate 202 is used for discharging the terminal pins 105. The fifth manipulator section 201 is configured to take the terminal pins 105 from the third part 200 and to fit the terminal pins 105 to the jig 119 when one of the jigs 119 is located at a feeding position (also referred to as a terminal pin feeding position 203) of the fifth manipulator section 201.

Specifically, since the terminal pins 105 are substantially regular in shape, in the present embodiment, the third vibration plate 202 is selected to sort and discharge the terminal pins 105, which can greatly improve the efficiency and accuracy of discharging the terminal pins 105.

A sixth cylinder 205 is provided at a position of the discharge port of the third vibration plate 202 (also referred to as a terminal pin discharge position 204), a second switching block 206 is connected to the sixth cylinder 205, and the second switching block 206 is provided with a terminal pin receiving groove 207 which is butted against the discharge port of the third vibration plate 202 to obtain the terminal pin 105. When the terminal pins 105 need to be obtained, the terminal pin receiving grooves 207 are butted with the discharge port of the third vibration plate 202, and after the terminal pins 105 are obtained, the sixth air cylinder 205 drives the second switching block 206 to switch positions so as to block the discharge port of the third vibration plate 202.

In addition, a fourth detection element 208 is provided at the terminal pin discharge position 204. The fourth detection element 208 is used to detect whether the terminal pin receiving groove 207 has received the terminal pin 105, and the fourth detection element 208 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

The fifth robot section 201 includes a second rotary robot 209 and a fifth gripper 210, the second rotary robot 209 may be a selectively rotatable PPU robot, and the fifth gripper 210 is mounted on the PPU robot. The second rotary robot 209 drives the fifth gripper 210 to switch between the terminal pin discharge position 204 and the terminal pin loading position 203. Thus, the fifth jaw 210 picks up the terminal pin 105 from the terminal pin discharge position 204, then transfers the terminal pin 105 to the terminal pin loading position 203, and fits the terminal pin 105 into the front side of the third mounting groove 111 of the bottom cover 101.

In addition, the terminal pin 105 and the movable contact piece 104 are installed in the third installation groove 111, and the terminal pin 105 is located at the left side of the movable contact piece 104. In order to ensure that the terminal pin 105 can be accurately mounted to the left side of the movable contact piece 104, a correction portion 211 is further provided at the terminal pin loading position 203. The correction part 211 comprises a correction cylinder 212 and a correction sheet 213, the correction sheet 213 is connected with the correction cylinder 212, and the correction cylinder 212 drives the correction sheet 213 to move up and down. The lower end of the correction piece 213 is provided with an inclined surface 214, and when the correction piece 213 is driven by the correction cylinder 212 to move downward, the inclined surface 214 of the correction piece 213 abuts against the movable contact piece 104 and pushes the movable contact piece 104 to the right. Thereby, a sufficient space is secured to the left side of the third mounting groove 111, thereby securing that the terminal pin 105 can be accurately mounted to the left side of the movable contact piece 104.

[ stationary contact mounting part 125]

Fig. 14 is a schematic view of the static contact mounting portion 125, with reference to fig. 14 and with additional reference to fig. 1, in some embodiments, to enable efficient and continuous loading of the static contacts 106, the static contact mounting portion 125 includes: a fourth dispensing part 215 and a sixth robot part 216. The fourth distributing portion 215 has a fourth vibrating disk 217, and the fourth vibrating disk 217 is used for discharging the static contact 106. The sixth manipulator section 216 is configured to take the static contact 106 from the fourth divided section 215 and to fit the static contact 106 to the jig 119 when one of the jigs 119 is located at a loading position (also referred to as a static contact loading position 218) of the sixth manipulator section 216.

Specifically, since the static contact 106 is substantially in a regular shape, in the present embodiment, the fourth vibration plate 217 is selected to sort and discharge the static contacts 106, which can greatly improve the efficiency and accuracy of discharging the static contacts 106.

A seventh cylinder 220 is provided at a discharge port of the fourth vibration plate 217 (also referred to as a static contact discharge position 219), the seventh cylinder 220 is connected to a third switching block 221, and the third switching block 221 is provided with a static contact receiving groove 222 which is abutted against the discharge port of the fourth vibration plate 217 to obtain the static contact 106. When the static contact 106 needs to be obtained, the static contact receiving groove 222 is in butt joint with the discharge hole of the fourth vibration disc 217, and after the static contact 106 is obtained, the seventh air cylinder 220 drives the third switching block 221 to switch positions so as to block the discharge hole of the fourth vibration disc 217.

Further, at the static contact piece discharging position 219, a fifth detecting element 223 is further provided. The fifth detecting element 223 is used to detect whether the static contact receiving groove 222 has acquired the static contact 106, and the fifth detecting element 223 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

The sixth robot section 216 includes a third rotary robot 224 and a sixth gripper 225, the third rotary robot 224 may be a selectively rotatable PPU robot, and the sixth gripper 225 is mounted on the PPU robot. The third rotary robot 224 drives the sixth holding jaw 225 to switch between the static contact discharge position 219 and the static contact charge position 218. Thus, after the sixth holding jaw 225 grips the static contact 106 from the static contact discharge position 219, the static contact 106 is transferred to the static contact loading position 218, and the static contact 106 is fitted to the fourth fitting groove 112 of the bottom cover 101.

[ spring mounting part 126]

Fig. 15 is a schematic view of the spring mounting portion 126, and in fig. 15, in order to facilitate viewing, fig. 15 is partially cut away, fig. 15 is referred to and fig. 1 is referred to as an auxiliary reference, and in some embodiments, in order to efficiently and continuously feed the spring 107, the spring mounting portion 126 includes: a fifth feed portion 226 and a seventh robot portion 227. The fifth material-dividing portion 226 has a fifth vibration plate 228, and the fifth vibration plate 228 is used for discharging the spring 107. The seventh manipulator section 227 is arranged to take the springs 107 from the fifth dispenser section 226 and to assemble the springs 107 to the clamps 119 when one of the clamps 119 is in the loading position (also called a spring loading position 229) of the seventh manipulator section 227.

The discharge end of the fifth vibratory pan 228 is provided with a first discharge pipe 230. After the springs 107 are sequenced by the fifth vibratory pan 228, they are sent to the seventh robot 227 through the first discharge pipe 230. The base 117 is provided with a tube opening/closing unit 231 so that the discharge of the spring 107 can be controlled. Specifically, the tube opening and closing part 231 includes a tube mounting seat 232, a lever 233, a lever driving cylinder 234 that drives the lever 233 to swing, and a return spring member 235 that returns the lever 233. Wherein the first discharging pipe 230 passes through the pipe mounting base 232. The lever 233 is hinged to the material pipe mounting block 232. When the lever drives the cylinder 234 to extend, the lever 233 is pushed to pivot, and the upper end of the lever 233 is disengaged from the first tapping pipe 230, thereby enabling the first tapping pipe 230 to be opened. When the lever-driving cylinder 234 is retracted, the return spring member 235 at the other end of the lever 233 drives the lever 233 to swing, and the upper end of the lever 233 abuts against the first discharging pipe 230, whereby the first discharging pipe 230 can be closed.

Furthermore, the fifth material division 226 further comprises a sixth detection element 236. The sixth detection element 236 is used to detect the spring 107 stored in the first tapping pipe 230, and the fifth vibratory disk 228 is temporarily deactivated if the spring 107 in the first tapping pipe 230 reaches a predetermined value. The sixth detection element 236 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

In addition, the seventh robot 227 includes an eighth cylinder 237 and a second discharge pipe 238, the eighth cylinder 237 drives the second discharge pipe 238 to move up and down, and the second discharge pipe 238 communicates with the first discharge pipe 230. When clamp 119 is in sprung position 229, eighth cylinder 237 drives second outlet tube 238 down and against top of mounting post 114 of press 102. The lever driving cylinder 234 drives the lever 233 to swing to open the first tapping pipe 230, and the spring 107 drops from the first tapping pipe 230 by gravity, and is discharged through the second tapping pipe 238, and is fitted to the mounting post 114 of the pressing member 102. After dropping a spring 107, the lever-driven cylinder 234 retracts, whereby the restoring spring element 235 pivots the lever 233 so that the lever 233 closes the first outlet pipe 230.

[ Upper cover mounting part 127]

Fig. 16 is a schematic diagram of the upper cover mounting part 127, and referring to fig. 16 and with the assistance of fig. 1, in some embodiments, in order to efficiently and continuously feed the upper cover 108, the upper cover mounting part 127 includes: a sixth separating part 239 and an eighth manipulator part 240. The sixth separating section 239 has a sixth vibrating tray 241, and the sixth vibrating tray 241 discharges the upper cover 108. The eighth manipulator section 240 is configured to obtain the upper cover 108 from the sixth dividing section 239 and assemble the upper cover 108 to the jig 119 when one of the jigs 119 is located at the feeding position (also referred to as the upper cover feeding position 242) of the eighth manipulator section 240.

Specifically, since the upper cover 108 is substantially regular in shape, in the present embodiment, the sixth vibrating plate 241 is selected to sort and discharge the upper covers 108, which can greatly improve the efficiency and accuracy of discharging the upper covers 108.

A ninth cylinder 244 is provided at a discharge port of the sixth vibration plate 241 (also referred to as an upper cover discharge position 243), a fourth switching block 245 is connected to the ninth cylinder 244, and the fourth switching block 245 is provided with an upper cover receiving groove 246 which is abutted against the discharge port of the sixth vibration plate 241 to obtain the upper cover 108. When the upper cover 108 is required to be obtained, the upper cover accommodating groove 246 is abutted to the discharge port of the sixth vibration plate 241, and after the upper cover 108 is obtained, the ninth cylinder 244 drives the fourth switching block 245 to switch the position so as to block the discharge port of the sixth vibration plate 241.

Further, a seventh detecting element 247 is provided at the upper lid discharging position 243. The seventh detecting element 247 is used to detect whether the upper cover receiving groove 246 is captured to the upper cover 108, and the seventh detecting element 247 may be selected from various sensors capable of detecting the presence or absence of a workpiece, such as a photoelectric sensor and an optical fiber sensor.

Further, in order to improve the assembling accuracy and prevent assembling errors, an eighth detecting element 248 is further provided above the upper cover discharging position 243. The eighth detecting element 248 is used for detecting whether the discharging direction of the upper cover 108 is correct. The eighth detection element 248 may be selected from various sensors capable of outputting different signals according to the distance, such as a photoelectric sensor and an optical fiber sensor, for example, and the eighth detection element 248 may be selected from a vision system element such as a CCD, for example. Specifically, since the shape of the left side of the upper cover 108 (having the sixth mounting groove 115 and the seventh mounting groove 116) is different from the shape of the right side of the inside of the bottom cover 101, the discharge direction of the upper cover 108 can be confirmed before the upper cover 108 is loaded by providing the eighth detecting element 248, and when the discharge direction of the upper cover 108 is different from the preset direction, the adjustment is performed by the eighth robot part 240.

The eighth robot section 240 includes a third switching drive section 249 capable of switching positions between the cap feeding position 243 and the cap feeding position 242, a second rotation drive section 250, and a seventh gripper 251 for gripping the cap 108, wherein the second rotation drive section 250 is mounted on the third switching drive section 249, and the seventh gripper 251 is mounted on the second rotation drive section 250. The third switching drive unit 249 can select a PPU robot. The second rotary driving part 250 includes a tenth cylinder 252 and a third gear 254 rack mechanism, wherein the tenth cylinder 252 and a third rack 253 of the third gear 254 rack mechanism are connected, and the seventh jaw 251 is connected to a third gear 254 of the third gear 254 rack mechanism. Therefore, when the eighth detecting element 248 detects that the discharging direction of the upper cover 108 is different from the preset direction, the tenth air cylinder 252 drives the third rack 253, so as to drive the third gear 254 to rotate, and thus drive the seventh clamping jaw 251 clamping the upper cover 108 to rotate to switch positions.

[ Blanking part 255]

Fig. 17 is a schematic view of the blanking portion 255, and referring to fig. 17 and with additional reference to fig. 1, in some embodiments, the base 117 is further provided with the blanking portion 255 outside the turntable 118, and the blanking portion 255 is disposed behind the upper cover mounting portion 127 along the direction of rotation of the turntable 118. Specifically, after the upper cover 108 is closed to the bottom cover 101, the assembly of the key 100 is completed. For this purpose, a blanking unit 255 is provided behind the upper cover mounting unit 127, the blanking unit 255 includes, for example, a known blanking robot 256 and a blanking flow path 257, and the blanking robot 256 grips the assembled key 100 from the jig 119 of the turntable 118 and drops the key 100 into the blanking flow path 257.

[ conduction detecting section 258]

Fig. 18 is a schematic view of the conduction detector 258, and referring to fig. 18 and with additional reference to fig. 1, in some embodiments, in order to distinguish between good products and defective products and to improve the yield of the key 100, the base 117 is further provided with the conduction detector 258 on the outer side of the turntable 118, and the conduction detector 258 is provided between the upper cover mounting portion 127 and the blanking portion 255 in the direction of rotation of the turntable 118. Specifically, since the pressing member 102 (pressing portion of the key 100) faces downward in a state where the key 100 is completely assembled, the conduction detecting portion 258 includes a stopper cylinder 259 provided above the base 117 and a pressing cylinder 260 provided below the base 117, and the stopper cylinder 259 moves from top to bottom and can press the key 100 to stopper the key 100. The push cylinder 260 is provided with a push rod 261, and the push cylinder 260 drives the push rod 261 to move from bottom to top and can push the push piece 102 to simulate the pushing action of the key 100. Specifically, the base 117 is further provided with an arc-shaped guide 262 at the mounting position of the conduction check portion 258, and when the jig 119 is rotated to the station of the conduction check portion 258, the escape block 134 slides along the arc-shaped guide 262 and is driven by the arc-shaped guide 262 to move in the direction of compressing the switching spring member 136. Thus, the second avoiding groove 135 of the avoiding block 134 communicates with the first avoiding groove 133, and the pressing cylinder 260 drives the push rod 261 to pass through the second avoiding groove 135 and the first avoiding groove 133, so as to press the pressing member 102. While the pressing operation of the key 100 is simulated, whether the key 100 is turned on is detected by a known detection device (not shown), and it is determined whether the key 100 is good or defective. When the key 100 is good, the feeding robot 256 feeds the key 100 into the feeding runner 257 when the key 100 is transferred to the feeding unit 255. When the key 100 is defective, the feeding robot 256 may put the key 100 into an NG product flow path (not shown) until an operator performs a process.

Referring to fig. 1 and 19, the key assembly machine of the present embodiment can complete the assembly of the key 100 by sequentially performing the following steps. Feeding a bottom cover 101 → feeding a pressing piece 102 → installing an elastic sheet 103 → installing a movable contact sheet 104 → installing a terminal pin 105 → installing a static contact sheet 106 → installing a spring 107 → installing an upper cover 108 → detecting a key 100 → blanking a product on the red and green sides.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. The button kludge for the equipment button, its characterized in that includes: the base station is arranged on the outer side of the rotary table and is provided with a bottom cover feeding portion, a pressing piece mounting portion, an elastic piece mounting portion, a movable contact piece mounting portion, a terminal pin mounting portion, a static contact piece mounting portion, a spring mounting portion and an upper cover mounting portion along the rotating direction of the rotary table.

2. The key assembling machine according to claim 1, wherein the base cover loading part includes:

the first material distributing part is provided with a first vibrating disc, and the first vibrating disc is used for discharging the bottom cover;

a first manipulator portion configured to take the bottom cover from the first material dividing portion and fit the bottom cover to the jig when one of the jigs is located at a feeding position of the first manipulator portion.

3. The key assembling machine according to claim 1, wherein said pusher mounting portion includes:

the second material dividing part is provided with a second vibrating disc, and the second vibrating disc is used for discharging the pressing piece;

a second manipulator portion configured to take the pressing piece from the second material dividing portion and to assemble the pressing piece to the jig when one of the jigs is located at a feeding position of the second manipulator portion.

4. The key assembling machine according to claim 1, wherein said dome mounting portion includes:

a first sheet feeding section configured to continuously feed one end of a first sheet in a roll shape;

a first sheet punching section configured to punch one end of the first sheet continuously fed out to form an elastic piece;

and the third mechanical hand part is used for obtaining the elastic sheet from the first sheet stamping part and assembling the elastic sheet to the clamp when one of the clamps is positioned at the feeding position of the third mechanical hand part.

5. The key assembling machine according to claim 1, wherein said movable contact mounting portion includes:

a second sheet feeding unit configured to continuously feed one end of a second sheet in a roll shape;

a second sheet punching section configured to punch one end of the second sheet continuously sent out to form a movable contact piece;

a fourth manipulator section configured to take the movable contact piece from the second sheet punching section and to fit the movable contact piece to the jig when one of the jigs is located at a feeding position of the fourth manipulator section.

6. The key assembling machine according to claim 1, wherein said terminal pin mounting portion includes:

the third material distributing part is provided with a third vibrating disc, and the third vibrating disc is used for discharging the terminal pins;

a fifth manipulator section configured to take the terminal pins from the third dividing section and fit the terminal pins to the jig when one of the jigs is located at a feeding position of the fifth manipulator section.

7. The key assembling machine according to claim 1, wherein said stationary contact mounting portion includes:

the fourth material distributing part is provided with a fourth vibrating disc, and the fourth vibrating disc is used for discharging the static contact pieces;

a sixth manipulator section configured to take the static contact from the fourth dividing section and assemble the static contact to the jig when one of the jigs is located at a feeding position of the sixth manipulator section.

8. The key assembling machine according to claim 1, wherein said spring mounting portion includes:

the fifth material dividing part is provided with a fifth vibrating disk, and the fifth vibrating disk is used for discharging the spring;

a seventh manipulator portion configured to obtain the spring from the fifth material dividing portion and to assemble the spring to the jig when one of the jigs is located at a feeding position of the seventh manipulator portion.

9. The key assembling machine according to claim 1, wherein said upper cover mounting portion includes:

the sixth material distributing part is provided with a sixth vibrating disk, and the sixth vibrating disk is used for discharging the upper cover;

an eighth manipulator section configured to obtain the upper cover from the sixth dividing section, and to assemble the upper cover to the jig when one of the jigs is located at a feeding position of the eighth manipulator section.

10. The key assembling machine according to claim 1, wherein the base is provided with a blanking portion on an outer side of the rotary disk, and the blanking portion is provided behind the upper cover mounting portion in a direction of rotation of the rotary disk.

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