WO2021176898A1 - Photoelectric sensor - Google Patents

Abstract

This photoelectric sensor is provided with: a case having an opening part; a first substrate which is a hard substrate disposed along a boundary plane dividing an internal space of the case into a first space on the opening part side and a second space on the opposite side; a light-projecting element for projecting detection light into a light-projecting optical fiber; a light-receiving element for receiving the detection light from a light-receiving optical fiber; a second substrate on which the light-projecting element and the light-receiving element are both mounted on one side of a mounting surface thereof, or which is connected at one side to a third substrate on which the light-projecting element and the light-receiving element are mounted, and is accommodated inside the second space; multiple buttons disposed in an opposite region of the mounting surface of the first substrate from the one side of the second substrate and receiving a user operation force applied from the opening part toward the first substrate; and a manifestative light-emitting element disposed in the opposite region of the mounting surface of the first substrate from the one side of the second substrate and indicating a specific button among the multiple buttons.

Description

Photoelectric sensor

The present invention relates to a photoelectric sensor.

A fiber-type photoelectric sensor in which an optical fiber for light projection and an optical fiber for light reception are inserted and removed is known (see, for example, Patent Document 1). The fiber-type photoelectric sensor detects whether or not the detection light projected onto the light projecting optical fiber is reflected by the detection target and returns to the light receiving optical fiber, or to what extent. This is a sensor that determines the presence / absence of a detection target and its distance. If the object to be detected is made of a translucent material, it is possible to detect the presence or absence of the object to be detected depending on whether the detected light is transmitted and the amount of light is attenuated.

Japanese Unexamined Patent Publication No. 2004-205209

Photoelectric sensors often have an operation unit that adjusts the detection level and switches the operation mode. When the operation unit includes a plurality of push buttons, those that have a particularly large effect if they are pressed incorrectly may be included. When such a special push button exists, there is a method of providing a light emitting portion in the vicinity thereof so as to make the push button stand out. However, since the photoelectric sensor is a sensor that detects the presence or absence of an object by using light, the light of the light emitting portion that makes the push button stand out may affect the detection system.

The present invention has been made to solve such a problem, and provides a photoelectric sensor that has a light emitting unit in the operation unit but does not adversely affect the sensing function.

The photoelectric sensor according to one aspect of the present invention is a hardware arranged along a boundary surface that divides a housing having an opening and an internal space of the housing into a first space on the opening side and a second space on the opposite side. The first substrate, which is a substrate, the light projecting element that projects the detection light onto the light projecting optical fiber, the light receiving element that receives the detected light from the light receiving optical fiber, and the light projecting element and the light receiving element are on one side of the mounting surface. The second substrate and the mounting surface of the first substrate, which are mounted closer to each other or connected to the third substrate on which the light projecting element and the light receiving element are mounted on one side and accommodated in the second space. A plurality of buttons provided in the area opposite to one side of the second board and receiving the user's operation force from the opening toward the first board, and one side of the mounting surface of the first board on the second board. It is provided in the area opposite to the one, and is provided with a light emitting element for specifying a specific button among a plurality of buttons.

In particular, by mounting a light emitting element for explicit indication, which clearly indicates the existence of a specific button, which is a button for which erroneous operation is desired, on the mounting surface of the first substrate, which is a hard substrate, in a region opposite to the light emitting / receiving element, the light is projected. It is possible to prevent the light from wrapping around in the vicinity of the optical element and the light receiving element. Further, since the push button is also arranged at a position away from the light emitting and receiving element, it is possible to reduce the transmission of an excessive load to the peripheral portion of the light emitting and receiving element.

It is preferable that the specific button in the above aspect is provided at the position farthest from the area corresponding to one side of the second substrate among the plurality of buttons. If it is arranged in such a position, erroneous operation can be further prevented. At this time, it is preferable that the light emitting element for explicit display is mounted between the specific button and a plurality of buttons other than the specific button. If the light emitting element for explicit display is provided at such a position, the specific button can be separated from other buttons, so that erroneous operation can be further prevented. It is also preferable to shorten the length of the first substrate in the longitudinal direction.

Further, the photoelectric sensor in the above aspect is mounted in a region corresponding to one side of the second substrate on the mounting surface of the first substrate, and includes an information light emitting element for presenting information toward the opening. The above-mentioned specific button is an adjustment button for starting the automatic adjustment of the reference value, and the above-mentioned plurality of buttons determine a change button for changing the numerical value displayed by the information light emitting element and a changed numerical value. It is preferable that the change button is provided adjacent to the information light emitting element, and the decision button is provided between the change button and the adjustment button. By adopting such an arrangement of buttons, it is possible to prevent erroneous operation of adjustment buttons and provide an intuitive user interface.

Further, the photoelectric sensor in the above aspect includes an opening / closing cover that covers at least a portion of the opening corresponding to the area where the plurality of buttons are provided, and the opening / closing hinge of the opening / closing cover has a specific button in the opening. It is preferable that it is provided at the end on the side where it is arranged. With such a configuration, since the opening / closing hinge is present in the vicinity of the adjustment button, the opening / closing cover prevents the user's finger from easily entering and prevents the adjustment button from being erroneously operated.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a photoelectric sensor in which the operation unit is provided with a light emitting unit but does not adversely affect the sensing function.

It is an overall perspective view of the photoelectric sensor which concerns on this embodiment. It is an overall perspective view which shows the state which opened the opening / closing cover. It is an exploded perspective view which shows the main component of a photoelectric sensor. It is a schematic diagram explaining the division space in a housing. It is a figure which shows the relationship of a UI unit, a base frame and a main board. It is sectional drawing which cut the state of FIG. 5 in the xz plane. It is a figure explaining each part of a UI unit. It is a figure which shows the relationship of a base frame, a main board and a shield plate. It is a perspective view which observed from one direction how the shield plate covers the main board. It is a perspective view which observed from the other direction how the shield plate covers the main board. It is a figure which shows the other structural example of a main board.

An embodiment of the present invention will be described with reference to the accompanying drawings. In each figure, those having the same reference numerals have the same or similar configurations. Further, in each figure, when there are a plurality of structures having the same or similar structure, a reference numeral is added to a part of the structure and the same reference numeral is omitted from the other parts in order to avoid complication. There is.

FIG. 1 is an overall perspective view of the photoelectric sensor 100 according to the present embodiment. The photoelectric sensor 100 according to the present embodiment is a fiber type optical fiber sensor, and whether or not the detection light projected on the light projecting optical fiber 142 is reflected by the detection object and returned to the light receiving optical fiber 143. Or, it is a sensor that determines the presence or absence of an object to be detected and its distance by detecting how much it returns. If the object to be detected is made of a translucent material, it is possible to detect the presence or absence of the object to be detected depending on whether the detected light is transmitted and the amount of light is attenuated.

The photoelectric sensor 100 has a flat box shape as a whole, and mainly the housing 190 and the opening / closing cover 110 that covers the upper part of the housing 190 so as to be openable / closable appear in the appearance. The housing 190 has two holes on the tip side. Specifically, it has an upper insertion hole 191 for inserting and removing the light emitting optical fiber 142 and a lower insertion hole 192 for inserting and removing the light receiving optical fiber 143. When the photoelectric sensor 100 is used, the light emitting optical fiber 142 is inserted and fixed in the upper insertion hole 191 and the light receiving optical fiber 143 is inserted and fixed in the lower insertion hole 192.

The housing 190 has a receiving portion of the connector unit 146 on the rear end side, and the figure shows a state in which the connector unit 146 is attached to the receiving portion. The connector unit 146 is provided at one end of the cable 147, and connects the power supply line and the signal line included in the cable 147 to the circuit board inside the housing 190.

The x-axis, y-axis and z-axis are defined as shown in the figure. In the subsequent drawings, the same coordinate axes as those in FIG. 1 are also shown to indicate the orientation of the structure represented by each drawing. Further, in the following description, as described above, the z-axis positive direction is upward, the negative direction is downward, the x-axis negative side is the front end side, the positive side is the rear end side, and the z-axis positive side is the upper side. The negative side may be referred to as the lower side, the direction along the x-axis may be referred to as the longitudinal direction, the direction along the y-axis may be referred to as the lateral direction, and the direction along the z-axis may be referred to as the height direction.

FIG. 2 is an overall perspective view showing a state in which the opening / closing cover 110 is opened. The opening / closing cover 110 can be rotated by a hinge structure described later, and the user can open the opening / closing cover 110 by lifting the tip side.

When the open / close cover 110 is opened, the UI unit 200 is exposed to the outside. The UI unit 200 mainly has a display unit 210 and an operation unit 220. More specifically, as will be described in detail later, the display unit 210 has a multi-digit numerical display arranged along the longitudinal direction. Further, the operation unit 220 also has push buttons arranged along the longitudinal direction.

The user can operate the push button by opening the open / close cover 110. If it is closed, it is possible to prevent the push button from being accidentally pressed. On the other hand, the opening / closing cover 110 is made of a transparent material, and the user can visually recognize the information presented by the display unit 210 even when the opening / closing cover 110 is closed.

FIG. 3 is an exploded perspective view showing the main components of the photoelectric sensor 100. The photoelectric sensor 100 is mainly composed of an opening / closing cover 110, a UI unit 200, a fiber lock mechanism 141, a connector unit 146, a base frame 150, a main board 170, a shield plate 180, and a housing 190. The housing 190 has an opening 193 on the upper side. That is, the internal space of the housing 190 is wide open upward. The UI unit 200, the fiber lock mechanism 141, the base frame 150, the main substrate 170, and the shield plate 180 are assembled and housed in the internal space of the housing 190 through the opening 193. The opening / closing cover 110 closes the opening 193. Further, the connector unit 146 is mounted from the rear end side of the housing 190.

The UI unit 200 is mainly composed of a mask sheet 121, a shading pad 122, a button pad 123, and a sub-board 130. The sub-board 130 is a rigid plate-shaped hard board, which is also called a rigid board, and for example, a glass epoxy board is used. One or more information LED 131, explicit LED 132, and tactile switch 133 are mounted on the mounting surface of the sub-board 130, respectively. The specific arrangement and configuration of these will be described in detail later.

The button pad 123 is a rubber molded sheet in which a key top corresponding to each tactile switch 133 and a base in contact with the mounting surface of the sub-board 130 are integrally formed. The button pad 123 is placed on the mounting surface of the sub-board 130 according to the arrangement of the tactile switch 133. The shading pad 122 is a light-shielding plate provided with through holes corresponding to the information LED 131, the explicit LED 132, and the button pad 123, and is arranged in close contact with the mounting surface of the sub-board 130. The shading pad 122 has a function of guiding the light from the information LED 131 and the explicit LED 132 toward the opening 193 and not leaking the light to other areas. The mask sheet 121 is a sheet on which a transmissive window frame that defines the outline of light from the information LED 131 and the explicit LED 132, and characters and icons that explain the role of the push button are printed. Like the shading pad 122, the mask sheet 121 is provided with a hole through which the key top of the button pad 123 is inserted, and is attached to the surface of the shading pad 122.

The fiber lock mechanism 141 clamps and fixes each of the light emitting optical fiber 142 inserted through the upper insertion hole 191 and the light receiving optical fiber 143 inserted through the lower insertion hole 192. The clamped end face of the light projecting optical fiber 142 faces the light projecting LED 161 and causes the detection light projected by the light projecting LED 161 to enter the optical fiber. The clamped end face of the light receiving optical fiber 143 faces the light receiving PD 162, and emits the detection light transmitted through the optical fiber to the light receiving PD 162.

The connector unit 146 connects the power supply line and the signal line included in the cable 147 to the corresponding terminals of the main board 170. The connector unit 146 may be configured to be detachable from the housing 190.

The base frame 150 forms the skeleton of the photoelectric sensor 100 and is molded of a thick resin so as not to be easily deformed. As shown in the figure, the base frame 150 has an L-shape as a whole, and functions as a base material on which the opening / closing cover 110, the UI unit 200, the fiber lock mechanism 141, the main substrate 170, and the shield plate 180 are attached. The specific shape and function will be described in detail later.

The main board 170 is a circuit board on which many elements for functioning the photoelectric sensor 100 are mounted, and in particular, a light projecting LED 161 and a light receiving PD 162 are mounted. In the present embodiment, a substrate having mounting surfaces on both sides is assumed, but a multilayer substrate having three or more layers may be used. The main substrate 170 is also a hard substrate like the sub substrate 130, and for example, a glass epoxy substrate is used.

The shield plate 180 is an electromagnetic shield plate that blocks electromagnetic waves from the outside toward the main substrate 170, and is formed by, for example, bending a copper plate. The shield plate 180 has a U-shape when observed from the longitudinal direction, and has an area that covers most of both mounting surfaces of the main substrate 170 by itself. The specific shape and the positional relationship with the base frame 150 and the main substrate 170 will be described in detail later.

FIG. 4 is a schematic view illustrating the divided space in the housing 190. As shown in the drawing, the sub-board 130 has a size corresponding to the opening 193, and when it is housed in the internal space of the housing 190, the internal space is opposite to the first space on the opening 193 side. It is divided into a second space on the side.

The first space is a space that mainly accommodates the UI unit 200 and integrates user interface functions using the opening 193. The second space is a space that mainly houses the fiber lock mechanism 141 and the main board 170, and integrates sensing functions such as a light emitting / receiving element and a signal processing circuit. In this way, by dividing the internal space of the housing 190 into two spaces by the sub-board 130 which is one hard board, the function that the phenomenon that can occur due to one space is executed in the other space is executed. The adverse effect on the above can be minimized.

The sub-board 130 has a GND wire 134 which is a ground wire surrounding an area in which the information LED 131, the explicit LED 132, and the tactile switch 133 are mounted. By providing such a GND wire 134, the effect of blocking electromagnetic waves from the opening 193 side toward the main substrate 170 can be expected. The GND line 134 does not have to be closed in an annular shape, and a certain blocking effect can be expected even if a part of the GND line 134 is missing. Further, the GND line 134 does not have to be in a line shape, and a region in which an element is not mounted may be used as a GND region.

FIG. 5 is a perspective view mainly showing the respective configurations of the UI unit 200, the base frame 150, and the main board 170 and their mutual arrangement relationships. The button pad 123, the shading pad 122, and the mask sheet 121 are laminated and assembled on the mounting surface of the sub-board 130, and together with the sub-board 130, form the UI unit 200.

The base frame 150 has an L-shape as a whole as described above. Specifically, it has an annular portion 151 that forms one side of the L-shape in the longitudinal direction, and an orthogonal portion 153 that extends orthogonally to the annular portion 151 and forms the other side of the L-shape in the height direction. The annular portion 151 is formed so as to orbit in the longitudinal direction and the lateral direction, and can receive the periphery of the lower surface of the sub-board 130.

The annular portion 151 is formed with one or more beam portions 152 formed so as to cross in the lateral direction, and the beam portions 152 support the lower surface of the sub-board 130. That is, the annular portion 151 and the beam portion 152 function as a sub-board receiving portion that receives the lower surface of the sub-board 130. Specifically, the sub-board 130 is placed on the sub-board receiving portion in the state of the UI unit 200, and is fixed by, for example, an adhesive. By adopting such a structure, the rigidity that does not easily deform even if the push button is strongly pressed by the user is ensured, and the sub-board 130 and the main board 170 are easily electrically connected at the time of assembly. Make it possible.

The main substrate 170 has a substantially rectangular shape, and is attached to the base frame 150 so that the vicinity of two orthogonal sides is supported by the annular portion 151 and the orthogonal portion 153, respectively. By attaching to the base frame 150 on two sides in this way, it is possible to further suppress distortion of the main substrate 170.

The fiber lock mechanism 141 is supported and fixed to the orthogonal portion 153 of the base frame 150. Since the fiber lock mechanism 141 has a function of accurately facing the end face of the light projecting optical fiber 142 and the end face of the light receiving optical fiber 143 to the light emitting LED 161 and the light receiving PD 162, respectively, it is particularly sensitive to misalignment. As shown in the figure, the fiber lock mechanism 141 has a box shape as a whole to increase the rigidity, and is further supported by the orthogonal portion 153 over the entire longitudinal direction, so that the fiber lock mechanism 141 is particularly distorted by an external load. It has a structure that does not easily cause misalignment.

FIG. 6 is a cross-sectional perspective view showing a state in which the annular portion 151 shown in FIG. 5 is cut in parallel with the xz plane near the center and observed from the positive side of the y-axis. In addition, priority is given to the legibility of the figure, and hatching of the cross section is omitted.

The light emitting LED 161 and the light receiving PD 162 are mounted close to the tip side, which is one side of the main board 170, and the light emitting portion and the light receiving portion are inserted into the fiber lock mechanism 141. More specifically, the light emitting LED 161 and the light receiving PD 162 are soldered to the mounting surface so that the light emitting portion and the light receiving portion project from the front end side edge of the main substrate 170.

The information LED 131 is mounted in a region corresponding to one side of the main board 170, that is, a region on the tip side of the mounting surface of the sub-board 130. The shading pad 122 arranged in close contact with the mounting surface of the sub-board 130 is provided with a through hole 125 corresponding to the information LED 131, and the through hole 125 emits light emitted by the information LED 131 in the opening 193 direction. Pass through.

The shading pad 122 may have at least the inner surface of the through hole 125 white and reflect the light emitted by the information LED 131 on the inner surface. By making the inner surface of the through hole 125 white in this way, the visibility of the information LED 131 can be improved. On the other hand, the shading pad 122 is preferably in close contact with the mounting surface of the sub-board 130 so as not to leak the light emitted by the information LED 131 to the space other than the through hole 125. Therefore, for example, the shading pad 122 may be heat-bonded to the mounting surface of the sub-board 130.

The tactile switch 133 is mounted in a region of the mounting surface of the sub-board 130 opposite to one side of the main board 170, that is, a region on the rear end side. The tactile switch 133 is a board-mounted type momentary operation switch. As shown in the figure, the button pad 123 has individual key tops 124 corresponding to the respective tactile switches 133, and the respective key tops 124 are connected by a thin portion. With such a configuration, when the user pushes down a specific key top 124 in the direction toward the sub-board 130, only the key top 124 is pushed down, and the bottom surface of the key top 124 pushes down the operation unit of the tactile switch 133 directly underneath to turn it on. To. When the user stops pressing, the key top 124 is lifted and the tactile switch 133 returns to the off state.

In this way, the tactile switch 133 is mounted on the hard board, and the ring portion 151 and the beam portion 152 of the base frame 150 receive the hard board. It does not cause large distortion in the structure. Further, even if the structure around the tactile switch 133 is slightly distorted, since the tactile switch 133 is mounted at a position far from the light emitting / receiving element, it is excessive to the peripheral portion of the light receiving / receiving element. It is possible to prevent the load from being transmitted. Further, since the tactile switch 133 and the information LED 131 are mounted on one hard substrate, it contributes to the ease of assembling the photoelectric sensor 100 in addition to ensuring the rigidity. Further, since the switch and the light emitting element are arranged on one hard board, good operability can be expected in that the user can easily operate while checking the information.

The explicit LED 132 is a light emitting element for clearly indicating the adjustment button described later to the user, and is mounted in the vicinity of the tactile switch 133 constituting the adjustment button on the mounting surface of the sub-board 130. The button pad 123 has a notch in the area where the explicit LED 132 is mounted, and the shading pad 122 has a through hole 125 for passing the light emitted by the explicit LED in the opening 193 direction.

In this way, since the information LED 131 and the explicit LED 132 are arranged on the first space side divided by the hard board, it is possible to suppress the light from wrapping around to the second space side. That is, it is possible to avoid the adverse effect of the light emitted by these on the sensing function. Further, since the hard substrate also suppresses the light of the light projecting LED 161 from wrapping around to the first space side, the possibility that the light of the light projecting LED 161 reduces the visibility of the display unit 210 is reduced.

In the present embodiment, the chip LED for 7-segment display is used as the light emitting element of the display unit 210, but other light emitting elements may be used. A display panel such as a small liquid crystal panel provided with a backlight or a self-luminous organic EL panel may be mounted on the sub-board 130 as a light emitting element. Further, the switch that receives the operation force of the user is not limited to the tactile switch, and may be a switch that can be surface-mounted. For example, a membrane switch in which a plurality of switches are continuously formed may be adopted. Further, the button pad 123 does not have to be a rubber molded sheet, and may be, for example, a resin molded product. Further, the key tops may not be connected to each other, and the surface-mounted switches may be individually provided with the key tops.

FIG. 7 is a view of the photoelectric sensor 100 in a state where the opening / closing cover 110 is closed, and is a view for explaining each part of the UI unit 200. As described above, each push button is composed of a tactile switch 133 and a key top 124 located above it. Here, the function and arrangement of each button arranged by such a combination will be described.

The operation unit 220 has four push buttons. Specifically, there are two change buttons 221 and an enter button 222 and an adjustment button 223. The two change buttons 221 are push buttons for changing the numerical value displayed on the display unit 210. If one of the + buttons is pressed, the numerical value is increased, and if the-button is pressed, the numerical value is decreased. The change button 221 is provided adjacent to the light emitting display unit 210.

The decision button 222 is a push button for determining a changed numerical value or a selected item. For example, the user can adjust the sensing response time while changing the numerical value of the display unit 210 with the change button 221 and press the enter button 222 to set the response time corresponding to the numerical value in the photoelectric sensor 100. Further, the change button 221 can be used to change the item, and the enter button 222 can be used to determine the changed item. The decision button 222 is also used as a mode switching button for switching between the operation mode and the setting mode. The decision button 222 is provided between the change button 221 and the adjustment button 223.

The adjustment button 223 is a push button that starts automatic adjustment of the reference value applied in the detection of the detected light. When the adjustment button 223 is pressed, the processing unit of the photoelectric sensor 100 executes optimum adjustment of the light projection power, the light receiving gain, and the detection threshold value so that the set detection value can be obtained.

When the adjustment button 223 is pressed, the adjustment value that was manually adjusted up to that point is discarded, so it is possible to prevent the adjustment button 223 from being accidentally pressed by the user or being pressed by touching something. I want to prevent it. Therefore, the adjustment button 223 is arranged at a distance from the adjacent decision button 222 and the other adjacent push buttons, and is arranged at the end of the plurality of push buttons. Since the change button 221 is arranged adjacent to the display unit 210, the adjustment button 223 is arranged on the rearmost end side of the UI unit 200.

The opening / closing cover 110 rotates around the hinge receiver 154 provided on the rearmost end side of the base frame 150. That is, since the hinge receiver 154 exists in the vicinity of the adjustment button 223, the open / close cover 110 hinders the user's finger from easily entering and makes it difficult to press the adjustment button 223.

The explicit LED 132 is provided so that the user can recognize the existence and the adjustment state of the adjustment button 223. Specifically, the explicit LED 132 is provided between the adjustment button 223 and the decision button 222, and a frame and characters are printed on the mask sheet 121 so that it can be seen that the LED is related to the adjustment button 223. .. For example, the explicit LED 132 blinks when the automatic adjustment is not performed, and lights up when the automatic adjustment is completed.

By arranging the explicit LED 132 that clearly indicates the existence and adjustment state of the special push button in the area on the rear end side of the mounting surface of the sub-board 130, which is a hard board, the light is emitted in the vicinity of the light-receiving element. Can be suppressed from wrapping around. That is, it is possible to avoid the adverse effect of the light emitted by the explicit LED 132 on the sensing function. Further, since the explicit LED 132 is arranged in a space away from the adjustment button 223 and the decision button 222 in order to prevent accidental pressing, it is also preferable for shortening the sub-board 130 in the longitudinal direction.

FIG. 8 is a diagram showing the relationship between the base frame 150, the main substrate 170, and the shield plate 180. The base frame 150 has an L-shape with the annular portion 151 and the orthogonal portion 153 as described above, but has a truss portion 155 connecting the annular portion 151 and the orthogonal portion 153 in a triangular plate shape as shown in the figure. Such a truss portion 155 increases the rigidity of the base frame 150.

The main board 170 has a first mounting surface 170a and a second mounting surface 170b. The first mounting surface 170a is provided with a GND land 171 connected to the ground wire and an amplification element 172 that amplifies the light receiving signal of the light receiving PD 162. The main board 170 has mounting holes 173 at a plurality of locations, is aligned with mounting portions 157 provided at corresponding locations of the base frame 150, and is fixed with screws. The truss portion 155 is located on the second mounting surface 170b side of the fixed main board 170. The truss portion is not provided on the first mounting surface 170a side.

Of the side edges of the four sides of the main board 170, which is a substantially rectangular shape fixed in this way, the side edge in the longitudinal direction facing the sub board 130 is the opening side edge 170c, and the bottom side when housed in the housing 190. The side edge in the longitudinal direction located at is defined as the bottom side edge 170d.

The shield plate 180 is an electromagnetic shield plate that blocks electromagnetic waves from the outside toward the main substrate 170, and has a shape that covers a circuit region of the first mounting surface 170a and the second mounting surface 170b in which electromagnetic waves are particularly desired to be blocked. Since the amplification element 172 is an element that is easily affected by electromagnetic waves from the outside, it is located in a circuit region covered by the shield plate 180. The shield plate 180 is formed by bending a metal veneer, which is a copper plate, for example, and has a U-shape as a whole when observed from the longitudinal direction. The shield plate 180 is arranged so as to take in the main substrate 170 inside the U-shape. More specifically, the shield plate 180 is arranged so as to cover the first mounting surface 170a and the second mounting surface 170b of the main board 170 so as to straddle the bottom side edge 170d on the side opposite to the opening side edge 170c. NS.

The arrangement surface 156 is a receiving surface provided on the orthogonal portion 153 for arranging the side portion of the shield plate 180 along the surface of the base frame 150. The arrangement surface 156 has an inclination such that the height of the opening side edge 170c side is higher than that of the bottom side edge 170d side with respect to the first mounting surface 170a of the main substrate 170. By providing such an inclination, the soldering work described later becomes easy.

FIG. 9 is a perspective view of the shield plate 180 covering the main substrate 170 from one direction. Specifically, it shows a state in which the first mounting surface 170a of the main substrate 170 is mainly covered with the first surface 180a of the shield plate 180. The side portion of the first surface 180a of the shield plate 180 is placed on the arrangement surface 156 provided on the orthogonal portion 153 and the arrangement surface 158 provided on the annular portion 151. As a result, the first surface 180a is maintained in a state of being separated from the first mounting surface 170a. That is, it does not come into contact with the element on the mounting surface, and there is no risk of damaging the circuit. The third surface 180c of the shield plate 180 is a shield surface following the first surface 180a, passes through the bottom side space of the bottom side edge 170d, and is connected to the opposite shield surface.

The shield plate 180 has an extending portion 181 extending from the first surface 180a toward the first mounting surface 170a. The extending portion 181 includes a bent portion 182 bent toward the bottom side edge 170d at the tip end portion thereof. The extending portion 181 is provided at a position corresponding to the GND land 171, and when the shield plate 180 is arranged on the base frame 150, the bent portion 182 comes into contact with the GND land 171. By soldering the bent portion 182 to the GND land 171, the ground wire of the main board 170 becomes the same potential (ground potential) as the shield plate 180. By providing such an extending portion 181, it is possible to absorb the floating of the shield plate 180 with respect to the first mounting surface 170a due to the variation during molding. Further, since the extending portion 181 bends even when an external force is applied to the shield plate 180, it is possible to prevent the solder from being damaged and breaking.

In the present embodiment, the GND land 171 is provided on the first mounting surface 170a at a position closer to the bottom side edge 170d than the opening side edge 170c. Since the GND land 171 is provided close to the bottom side edge 170d in this way, the extension portion 181 is caught by the element on the first mounting surface 170a and deformed when the shield plate 180 is assembled. 1 It is possible to avoid a problem of damaging the element mounted on the mounting surface 170a.

Further, since the bent portion 182 is bent toward the bottom side edge 170d, in the step of assembling the shield plate 180 to the base frame 150, the bent portion 182 is slid and positioned according to the surface of the first mounting surface 170a. NS. Therefore, even if the GND land 171 is provided at a position slightly away from the bottom side edge 170d, it is possible to avoid a problem that the extension portion 181 is bent in the middle during assembly.

Further, as described above, since the arrangement surface 156 has an inclination such that the height of the opening side edge 170c side is higher than that of the bottom side edge 170d side with respect to the first mounting surface 170a, the shield plate 180 is assembled more stably. be able to. Further, since the length of the extending portion 181 can be shortened by that amount, soldering becomes easy. Further, as described above, since the base frame 150 is not provided with the truss portion on the first mounting surface 170a side, the soldering work can be easily performed.

FIG. 10 is a perspective view of the shield plate 180 covering the main substrate 170 as observed from another direction. Specifically, it shows a state in which the second mounting surface 170b of the main board 170 is mainly covered with the second surface 180b of the shield plate 180. The second surface 180b is a shield surface continuous from the above-mentioned third surface 180c. The peripheral edge portion including the side portion of the second surface 180b is placed on the surface of the truss portion 155 continuous with the orthogonal portion 153 and arranged. As a result, the second surface 180b is maintained in a state of being separated from the second mounting surface 170b.

A retaining hole 183 is provided on the second surface 180b of the shield plate 180. Further, the truss portion 155 of the base frame 150 is provided with a lashing claw 159 for tying the lashing hole 183. The retaining hole 183 fits into the retaining claw 159 when the shield plate 180 is slid toward the opening so as to sandwich the main substrate 170. In this way, the assembling worker can easily assemble the shield plate 180 to the base frame 150. Further, when the second surface 180b side is connected to the base frame 150 in this way, the soldering work performed on the first surface 180a side becomes easy.

The retaining hole 183 is preferably provided on the second surface 180b. That is, the anchoring hole 183 and the anchoring portion by the anchoring claw 159 are provided not on the side of the first mounting surface 170a but on the side of the second mounting surface 170b. Since the first surface 180a covers the amplification element 172 that is easily affected by electromagnetic waves from the outside, it is preferable not to provide a hole that can serve as an entry path for electromagnetic waves. The tether claw 159 may be provided on the orthogonal portion 153, but if the truss portion 155 is used as the arrangement surface of the second surface 180b as in the present embodiment, the tether claw 159 is also provided on this arrangement surface. It is preferable to provide it.

As described above, by adopting the U-shaped shield plate 180, the number of parts and the assembly man-hours can be reduced as compared with shielding each mounting surface individually. In particular, by providing the extension portion 181, it can be easily connected to the ground wire of the main board 370, and the state of being separated from the mounting surface of the main board 370 can be maintained. Further, since the sub-board 130 can also block electromagnetic waves from the outside toward the main board 370 to some extent, the shield plate 180 straddles the bottom side edge 170d of the main board 170 and covers both mounting surfaces, so that the entire circumference is covered from the outside. The influence of electromagnetic waves can be reduced.

FIG. 11 is a diagram showing another configuration example of the main board. In the embodiments described so far, the case where the light projecting LED 161 and the light receiving PD 162 are mounted on the main board 170 has been described. However, in the configuration in which the internal space of the housing 190 is divided into the first space and the second space by the sub-board 130 which is a hard board, the main board 170 does not have to be a single board. That is, from the viewpoint of preventing the excessive load due to the push button operation from being transmitted to the peripheral portion of the light receiving / receiving element and preventing the stray light of the light emitting element from reaching the peripheral portion of the light receiving element, the second There may be a plurality of substrates accommodated in the space.

FIG. 11 shows a configuration example in which the light emitting / receiving board 380 on which the light emitting LED 161 and the light receiving PD 162 are mounted is separated from the main board 370. The main board 370 and the light receiving / receiving board 380 are electrically connected via, for example, a connector. Further, the main substrate 370 may have a configuration supported by the fiber lock mechanism 141. It is preferable that the shield plate 180 is arranged so that the light emitting / receiving substrate 380 is also taken into the U-shape together with the main substrate 370.

The above photoelectric sensor 100 is configured so that the various effects described above can be obtained together. Therefore, it may not be possible to adopt certain configurations that have ancillary effects due to other technical requirements. Even in such a case, the embodiment according to the present invention can be used as long as the configuration is such that the effect mainly intended by the present invention can be obtained. For example, if it is mainly intended to prevent the light of the explicit LED 132 arranged on the mounting surface of the sub-board 130 from wrapping around the peripheral portion of the light-receiving element, the sub-board 130 has a size corresponding to the opening. It doesn't have to be. Specifically, it may be arranged along the boundary surface that separates the first space and the second space, and may have a size that prevents stray light. Further, the shield plate 180 does not have to be U-shaped.

Further, in the above photoelectric sensor 100, the adjustment button 223 is provided as a specific button for which erroneous operation is particularly desired to be prevented, but the specific button is not limited to the adjustment button and may be a button for executing other functions. For example, it may be a reset button that returns all the set values to the initial values. Further, the specific button is not limited to one, and may be two or more. In that case, those specific buttons may be regarded as one group, and the group may be arranged at the position on the rearmost end side of the sub-board 130. Further, the number of light emitting elements that clearly indicate the specific button is not limited to one, and may be two or more. For example, two or more LEDs may make the adjustment button stand out. Further, the light emitting element that clearly indicates the specific button is not limited to the case where the light is emitted at a position adjacent to the specific button, and may be configured such that the specific button itself emits light by interposing a light guide member, for example.

[Appendix]
A housing (190) having an opening (193) and
A first substrate (130), which is a hard substrate arranged along a boundary surface that divides the internal space of the housing (190) into a first space on the opening side and a second space on the opposite side.
A light projecting element (161) that projects the detected light onto the light projecting optical fiber (142), and
A light receiving element (162) that receives detection light from a light receiving optical fiber (143), and a light receiving element (162).
The light projecting element (161) and the light receiving element (162) are mounted close to one side of the mounting surface (170a, 170b), or the light emitting element (161) and the light receiving element (162) are mounted. The second substrate (170, 370), which is connected to the third substrate (380) on one side and accommodated in the second space,
It is provided in a region of the mounting surface of the first substrate (130) opposite to the one side of the second substrate (170, 370), and from the opening (193) to the first substrate (130). Multiple buttons (221, 222, 223) that receive the operation force of the user who is heading,
A reference value among the plurality of buttons (221, 222, 223) provided on the mounting surface of the first substrate (130) opposite to the one side of the second substrate (170, 370). A photoelectric sensor (100) including a light emitting element (132) for specifying an adjustment button (223) for initiating automatic adjustment of the above.

100 ... photoelectric sensor, 110 ... Open / close cover, 121 ... Mask sheet, 122 ... Shading pad, 123 ... Button pad, 124 ... Key top, 125 ... Through hole, 130 ... Sub-board, 131 ... Information LED, 132 ... For explicit use LED, 133 ... Tactile switch, 134 ... GND line, 141 ... Fiber lock mechanism, 142 ... Optical fiber for floodlight, 143 ... Optical fiber for light receiving, 146 ... Connector unit, 147 ... Cable, 150 ... Base frame, 151 ... Circular Part, 152 ... Beam part, 153 ... Orthogonal part, 154 ... Hinge receiver, 155 ... Truss part, 156 ... Arrangement surface, 157 ... Mounting part, 158 ... Arrangement surface, 159 ... ... Light receiving PD, 170 ... Main board, 170a ... First mounting surface, 170b ... Second mounting surface, 170c ... Opening side edge, 170d ... Bottom side edge, 171 ... GND land, 172 ... Amplifying element, 173 ... Mounting hole, 180 ... Shield plate, 180a ... 1st surface, 180b ... 2nd surface, 180c ... 3rd surface, 181 ... Extension part, 182 ... Bent part, 183 ... Binding hole, 190 ... Housing, 191 ... Upper insertion Hole, 192 ... Lower insertion hole, 193 ... Opening, 200 ... UI unit, 210 ... Display, 220 ... Operation, 221 ... Change button, 222 ... Enter button, 223 ... Adjustment button, 370 ... Main board, 380 ... Light receiving / receiving board

Claims (5)

1. A housing with an opening and
   A first substrate, which is a hard substrate arranged along a boundary surface that divides the internal space of the housing into a first space on the opening side and a second space on the opposite side.
   A light projecting element that projects detection light onto a light projecting optical fiber,
   A light receiving element that receives detection light from a light receiving optical fiber and
   The light emitting element and the light receiving element are mounted close to one side of the mounting surface, or the light emitting element and the light receiving element are connected to a third substrate on which the light receiving element is mounted on the one side. The second substrate housed in two spaces and
   A plurality of buttons provided in a region of the mounting surface of the first substrate opposite to the one side of the second substrate and receiving an operation force of a user from the opening toward the first substrate.
   A photoelectric sensor provided in a region of the mounting surface of the first substrate opposite to the one side of the second substrate, and provided with a light emitting element for specifying a specific button among the plurality of buttons.
2. The photoelectric sensor according to claim 1, wherein the specific button is provided at a position farthest from the region corresponding to the one side of the second substrate among the plurality of buttons.
3. The photoelectric sensor according to claim 2, wherein the explicit light emitting element is mounted between the specific button and the plurality of buttons other than the specific button.
4. A light emitting element for information, which is mounted on a region of the mounting surface of the first substrate corresponding to the one side of the second substrate and for presenting information toward the opening, is provided.
   The specific button is an adjustment button that starts automatic adjustment of the reference value.
   The plurality of buttons include a change button for changing a numerical value displayed by the information light emitting element and a decision button for determining the changed numerical value.
   The photoelectric change button according to any one of claims 1 to 3, wherein the change button is provided adjacent to the information light emitting element, and the decision button is provided between the change button and the adjustment button. Sensor.
5. An opening / closing cover is provided to cover at least a portion of the opening corresponding to the area where the plurality of buttons are provided.
   The photoelectric sensor according to any one of claims 1 to 4, wherein the opening / closing hinge of the opening / closing cover is provided at the end of the opening on the side where the specific button is arranged.

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