Abstract:
A push button switch provided with a multistage actuation interlock function is composed of a casing; a pair of push buttons arranged side by side passing through an upper lid of the casing; a plurality of movable bodies arranged movably in a direction perpendicular to a depression direction of the push buttons into the casing; a plurality of movable contacts attached to the movable bodies, respectively; and a plurality of fixed contacts arranged on a base portion of the casing in confronting positional relationship with respect to the movable contacts. When each of the push buttons is depressed at each of the multistage stroke, the movable body is shifted to bring the movable contact into contact with the fixed contact, respectively in sequence. Further, an interlock plate is interposed between and associated with the two push buttons in the casing.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a push button switch provided with a multistage actuation interlock function for actuating a plurality of switches at multiple stages, which is suitable for use to control a motor for driving a hoist, a chain block, etc. at a plurality of stages of speed. 
     2. Description of the Prior Art 
     The push button switch provided with a two-stage actuation interlock function used for reversibly rotating a motor for driving a hoist, a chain block, etc. has been already disclosed in JP-Y-4-31686. The prior art push button switch as described above is provided with an interlock plate pivotally supported by a fixed axle, and a pair of movable bodies for actuating each of both ends of the interlock plate. An upper end of each of the movable bodies projects out of a casing so as to function as a push button. Each of the movable bodies is formed with a recessed portion on both side portions thereof, respectively. Further, a lid body is formed with a stepped portion in correspondence to the recessed portion, respectively. Further, a mutually-operative bearing and spring assembly is provided at the corresponding recessed portion and the stepped portion, respectively. Since the prior art push button switch is constructed as described above, it is possible to realize a push button switch provided with a two-stage switching function. 
     Here, when a three-stage push button switch is required to be constructed on the basis of the structure which is basically the same as the above-mentioned prior art push button switch provided with the two-stage actuated interlock plate, the size of the push button switch inevitably increases, as shown in FIGS. 1(A) to 1(D). 
     In more detail, with reference to FIGS. 1(A) to 1(D), an internal space of a casing 1 is divided symmetrically into right and left sides, and an interlock plate 16 is pivotally provided so as to be pivotal about a fixed axle 17 mounted horizontally at the middle bottom portion of the casing 1. A pair of push buttons 20a and 20b movable in the vertical direction are arranged so as to project out of the upper portion of the casing 1. Under the lower end of each of the push buttons 20a and 20b, a movable body 21a or 21b is attached, respectively. Whenever the push button 20a or 20b is actuated, the interlock plate 16 is pivoted by being pushed by the movable body 21a or 21b. Each of the movable bodies 21a and 21b has one set of three movable contacts 18a, 18b and 18c, respectively. On the other hand, on the bottom surface of the casing, one set of three fixed contacts 19a, 19b and 19c are provided so as to be opposed to the three movable contacts 18a, 18b and 18c, respectively. Therefore, whenever the push button 20a or 20b is depressed, these three movable contacts 18a, 18b and 18c are closed (turned on) so as to contact the fixed contacts 19a, 19b and 19c selectively in sequence according to the stroke of the push button 20a or 20b. Here, a pair comprising the movable contact 18a and the fixed contact 19a constitutes the first stage contacts; a pair comprising the movable contact 18b and the fixed contact 19b constitutes the second stage contacts; and a pair comprising the movable contact 18c and the fixed contact 19c constitutes the third stage contacts. Movable contacts 18a to 18c are provided with a contact spring 22 (shown in FIG. 1(A)), respectively, to obtain a predetermined respective contact pressure. 
     FIG. 1(A) shows the state where the two push buttons 20a and 20b are both not depressed so that the push button switch is completely turned off. FIG. 1(B) shows the state where the first button 20a is depressed so that the pair comprising the first-stage movable contact 18a and the fixed contact 19a are in contact with each other. FIG. 1(C) shows the state where the first button 20a is further depressed deeper so that the pair comprising the second-stage movable contact 18b and the fixed contact 19b are in contact with each other in addition to the first-stage movable and fixed contacts 18a and 19a. FIG. 1(D) shows the state where the first push button 2a is furthermore depressed deeper so that the pair comprising the third-stage movable contact 18c and the fixed contact 19c are in contact with each other in addition to the first- and second-stage movable and fixed contacts 18a, 18b and 19a, 19b (all pairs of the movable and fixed contacts are in contact with each other only on the side of the push button 20a). 
     As is well-understood with reference to FIGS. 1(A) to (D), when the third-stage contact pairs are required to be closed to each other completely, since the push button 20a must be depressed deeply in the downward direction, the interlock plate 16 is inevitably pivoted clockwise through a large angle by the movable body 21a, with the result that there exists a problem in that the size of the entire push button switch inevitably increases. 
     SUMMARY OF THE INVENTION 
     With these problems in mind, therefore, it is the object of the present invention to provide a push button switch provided with a multistage actuation interlock function, by which the contacts can be closed at multiple stages without increasing the stroke of the push buttons and the size of the interlock plate. 
     To achieve the above-mentioned object, the present invention provides a push button switch provided with a multistage actuation interlock function, which comprises: a casing; a pair of push buttons arranged side by side passing through an upper lid of said casing; a plurality of movable bodies arranged movably in a direction perpendicular to a depression direction of said push buttons into said casing; a plurality of movable contacts attached to said movable bodies, respectively; a plurality of fixed contacts arranged on a base portion of said casing in confronting positional relationship with respect to said movable contacts, wherein whenever each of said push buttons is depressed at multistage strokes, each of said movable body is shifted to bring each of said movable contacts into contact with each of said fixed contacts, respectively in sequence; and an interlock mechanism interposed between and associated with a pair of said push buttons within said casing. 
     That is, to achieve the above-mentioned object, in the push button switch provided with a multistage actuation interlock function according to the present invention, two return springs are provided on both sides of the lower portion of a groove formed by two middle thin-walls of the base portion of the casing body; two push buttons are each formed with a stepped portion each having a projection on both sides thereof respectively, with three downwardly sloped portions extending perpendicular to the stepped portion (one on one side thereof and two on the other side thereof), an engaging portion also perpendicular to the stepped portion on one side thereof, and a straight portion also perpendicular to the stepped portion on the other side thereof. The two push buttons are provided on the two return springs, respectively. A triangular cross section projection is formed at the middle base portion of the middle thin-walled groove of the base portion of the casing body. Further, an interlock plate is formed with a lower convex projection, with two upper right and left axle portions extending in two opposite directions, respectively at both upper right and left sides thereof, and with two cutout portions. The axle portions of the interlock plate are engaged with the engaging portions of the push buttons, respectively. A plurality of movable bodies movable in the direction perpendicular to the actuation direction of the push buttons are arranged in the base horizontal direction of the casing; and further the fixed contacts brought into contact with the movable contacts of the movable bodies are arranged also in the base horizontal direction of the casing. 
     In the push button switch according to the present invention, it is possible to construct the push button switch provided with a multistage actuation interlock function, without increasing the size of the interlock or the stroke of the push buttons. In this case, since the two movable bodies located at the middle portion of the casing and between the two push buttons are constructed by a single structure and further since the movable contacts and the fixed contacts are arranged in a direction perpendicular to the actuation direction of the push buttons into the casing, it is possible to simplify the connection between the contacts by use of connection plates when the electrical interlock function is required, thus simplifying the wiring work markedly. 
     The push button switch provided with the multistage actuation interlock function of this type is usually used as a pendant switch. In this case, the prior art push button switch is often actuated erroneously due to an external shock applied along the push button actuation direction from an external structure. In the push button switch according to the present invention, however, since the contacts are arranged in the direction perpendicular to the actuation direction of the push buttons, it is possible to effectively prevent the push button switch from being actuated erroneously by an external shock. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1(A) to 1(D) are cross-sectional views showing the internal arrangements of the prior art push button switch provided with a multistage actuation interlock function, in which the open-closed conditions of the switches are shown at each of the multiple stages; 
     FIG. 2 is a front view showing an embodiment of the push button switch provided with a multistage actuation interlock function according to the present invention; 
     FIG. 3 is a cross-sectional view taken along the line 3--3 in FIG. 2; 
     FIG. 4 is a front view showing the push button switch according to the present invention, in which the casing is removed; 
     FIG. 5 is an exploded view showing the push button switch according to the present invention; 
     FIG. 6 is a wiring diagram showing an example of the application of use of the contacts of the push button switch according to the present invention; 
     FIG. 7 is a back view showing the push button switch according to the present invention; 
     FIGS. 8(A) to 8(D) are cross-sectional views taken along section lines 8A--8A, 8B--8B, 8C--8C and 8D--8D of FIG. 4, showing the push button switch according to the present invention, for assistance in explaining the movements of the normal open switches at the first to third stages (strokes); 
     FIGS. 9(A), 9(C) and 9(E) are cross-sectional views for assistance in explaining the movement of the interlock plate of the push button switch according to the present invention at different open-closed conditions; and 
     FIGS. 9(B), 9(D) and 9(F) are cross-sectional views for assistance in explaining the movement of the movable contacts of the push button switch according to the present invention in correspondence to the interlock plate movement shown in FIGS. 9(A), (C) and 9(E), respectively. 
    
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS 
     The push button switch provided with a multistage actuation interlock function according to the present invention will be described in detail hereinbelow with reference to the attached drawings, on the basis of an embodiment of a three-stage actuated push button switch, by way of example. 
     With reference to FIGS. 2 and 7, two push buttons 2a and 2b are provided within a casing 1 so as to pass through two holes 1b and 1c formed on a lid la of the casing 1. Two return springs 8a and 8b are arranged between the two push buttons 2a and 2b and the bottom surface of the casing 1. Further, as shown in FIG. 5, each of the two push buttons 2a and 2b is formed with a stepped portion 2c on two opposing side surfaces thereof, respectively, to locate the multistage (three stage) positions of the push button 2a or 2b. Further, each of the push buttons 2a and 2b is formed with three downward sloping portions of different lengths (a long sloping portion 2i, a middle sloping portion 2h, and a short sloping portion 2d), respectively, on both opposing side surfaces thereof perpendicular to the stepped portions 2c. In FIG. 5, the short sloping portion 2d of the push button 2a and the long and middle sloping portions 2i and 2h of the push button 2b are both not visible in the perspective view of FIG. 5. The downward slopping portions 2d, 2h and 2i are used to slide (move) a plurality of movable bodies 9a to 9d and 10a and 10b in the horizontal direction, as described below in detail. Further, each of the push buttons 2a and 2b is formed with a vertical straight portion 2e on one of the two opposing side surfaces thereof and an engaging portion 2g (having a semicircular recessed portion 2f) on the other of the two opposing side surfaces thereof, both perpendicular to the stepped portions 2d. 
     As shown in FIG. 5, various parts are all arranged within the casing 1. The casing 1 has a middle wall 1d substantially composed of two thin-walled plates so as to form a thin groove portion 3 therebetween in such a direction as to extend along the middle portion of the casing 1 in the longitudinal direction of the casing 1 (the right and left direction in FIG. 2 or FIG. 5). The wall 1d is cut away so as to form the right and left gaps 1e and 1f symmetrically. Further, as shown in FIG. 3, a triangular cross-sectional projection 5 is formed on the inner bottom surface of the casing 1 so as to cross the groove portion 3 (perpendicular to the wall 1d). 
     With reference to FIGS. 3 and 5, the relationship between the push buttons 2a and 2b, the interlock plate 7, and the casing 1 will be explained hereinbelow. The two return springs 8a and 8b are disposed in the two gaps 1e and 1f of the wall 1d. The two push buttons 2a and 2b are mounted on the return springs 8a and 8b, respectively, such that the vertical straight portions 2e of the push buttons 2a and 2b can be slid in the wall 1d (between the two thin-walled plates of the wall 1d). Further, the interlock plate 7 is formed with two axle portions 7a and 7b extending in two opposite directions, respectively, along the lateral direction of the casing 1 (the upper and lower direction in FIG. 2), respectively on both the upper right and left sides thereof. Further, the interlock plate 7 is formed with two cutout portions 7c and 7d on the projection sides of the axle portions 7a and 7b, respectively. Further, a convex curved portion 7e is formed at the lower end of the interlock plate 7 symmetrically. Here, as shown in FIG. 3, the two axle portions 7a and 7b formed in the interlock plate 7 are engaged with the two semicircular portions 2f formed in the engage portions 2g of the two push buttons 2a and 2b, respectively. Here, since the axial length of the two axle portions 7a and 7b are roughly equal to the depth of the cutout portions 7c and 7d formed in the interlock plate 7, even if the push buttons 2a and 2b are engaged with the interlock plate 7, the interlock plate 7 can be movable within the groove 3 of the wall 1d. Therefore, when the push buttons 2a and 2b are depressed from the outside, the push buttons 2a and 2b can be moved up and down through the two holes 1b and 1c formed in the lid 1a of the casing 1 and guided along the two thin-walled plates of the wall 1d, respectively. With reference to FIG. 5, the four small movable bodies 9a, 9b, 9c and 9d are arranged on the outer side of the casing 1. Each small movable body 9 is formed with a window 9e for accommodating a movable contact and with a triangular upward sloping portion 9f (when brought into contact with the downward sloping portion of the push button, moved in the horizontal direction). On the other hand, the two large movable bodies 10a and 10b are arranged on the inner side of the casing 1. Each large movable body 10 is formed with two windows 10c and 10d for accommodating two movable contacts, respectively, with a middle recessed portion 10e between the two windows 10c and 10d, and with a triangular upward sloping portion 10f (when brought into contact with the downward sloping portion of the push button, moved in the horizontal direction). 
     FIG. 5 shows the assembly positions of the two push buttons 2a and 2b, the interlock plate 7, the two return springs 8a and 8b, the four small movable bodies 9a to 9d, and the two large movable bodies 10a and 10b in the casing 1. 
     With reference to FIGS. 4 and 5, the two push buttons 2a and 2b are engaged with the interlock plate 7 by engaging the two axle portions 7a and 7b of the interlock plate 7 with the engaging portions 2g of the two push buttons 2a and 2b, and then inserted into the groove portion 3 of the wall 1d vertically standing within the casing 1 (as shown in FIG. 3). 
     As shown in FIG. 5, within the casing 1, two spaces 12 and 13 are formed on both sides of the wall 1d between one surface of the wall 1d and an inner casing wall 13a in such a way as to be opposed to each other. Further, a projected portion 11 is formed between the two spaces 12 and 13 on each side of the inner casing wall 13a (so as to face the wall 1d). Therefore, the recessed portion 10e of each of the two large movable bodies 10a and 10b is engaged with the projected portion 11, respectively, such that the triangular upward sloping portion 10f of the large movable body 10a can be located on the right side in FIG. 5 and the triangular upward sloping portion 10f of the large movable body 10b can be located on the left side in FIG. 5. 
     Further, the four small movable bodies 9a, 9b, 9c and 9d are arranged in the four spaces 12 and 13 of the casing 1, respectively, as shown in FIG. 5, such that the upward sloping portion 9f of each of these movable bodies 5 is directed inward. Here, as shown in FIG. 4, the two small movable bodies 9a and 9c are provided with a movable contact 18b, respectively, and the two small movable bodies 9b and 9d are provided with a movable contact 18c, respectively. These movable contacts 18b and 18c are all attached to the four movable bodies 9a to 9e, respectively, so as to be directed outwardly of the casing 1 horizontally and to confront a fixed contact, respectively. 
     In more detail, with reference to FIG. 4, the movable contact 18b of the movable body 9a can be brought into contact with a fixed contact fixed to a terminal plate 14g when the movable body 9a is moved rightward by the push button 2a. The movable contact 18c of the movable body 9b can be brought into contact with a fixed contact fixed to a terminal plate 14f when the movable body 9b is moved rightward by the push button 2a. The movable contact 18b of the movable body 9c can be brought into contact with a fixed contact fixed to a terminal plate 14c when the movable body 9c is moved leftward by the push button 2b. The movable contact 18c of the movable body 9d can be brought into contact with a fixed contact fixed to a terminal plate 14b when the movable body 9d is moved leftward by the push button 2b. Each of these terminal plates 14b, 14c, 14f and 14g are all formed into an L-shape and has a terminal portion (connected to an external load through a lead) at each end thereof, respectively. 
     On the other hand, the two large movable bodies 10a and 10b are arranged in the two spaces each formed between the spaces 12 and 13 of the casing 1, respectively, as shown in FIG. 5, such that the upward sloping portion 10f of each of the movable bodies 10a and 10b are directed outward of the casing 1. Here, each of the two large movable bodies 10a and 10b is provided with two movable contacts 18a and 18d, respectively, as shown in FIG. 4. The movable contacts 18a and 18d are all attached to the two large movable bodies 10a to 10b, respectively, so as to be directed horizontally inward of the casing 1 and to confront a fixed contact, respectively. 
     In more detail, with reference to FIG. 4, the movable contact 18a of the movable body 10a can be brought into contact with a fixed contact fixed to a terminal plate 14d when the movable body 10a is moved leftward by the push button 2a. The movable contact 18d of the movable body 10a is in contact with a fixed contact fixed to a terminal plate 14a even if the movable body 10a is not moved by the push button 2a. The movable contact 18a of the movable body 10b can be brought into contact with a fixed contact fixed to a terminal plate 14h when the movable body 10b is moved rightward by the push button 2b. The movable contact 18d of the movable body 10b is in contact with a fixed contact fixed to a terminal plate 14e even if the movable body 10b is not moved by the push button 2a. Each of these terminal plates 14a, 14d, 14e and 14h is formed into an L-shape and has a terminal portion (connected to an external load through a lead) at each end thereof, respectively. 
     Therefore, when the two push buttons 2a and 2b are both not depressed, the eight switches are positioned as shown in FIG. 4, in which it should be noted that the two movable contacts 18d of the movable bodies 10a and 10b are both normally-closed contacts, respectively, and the other remaining movable contacts are all normally-open contacts. 
     Therefore, when the push button 2a is depressed at a first stroke, the long downward sloping portion 2i of the push button 2a (projecting from the gap 1e) is brought into contact with the upward sloping portion 10f of the large movable body 10a (moved leftward) to close the contacts 18a and 19a and open the interlock contacts 18d and 19d thereof. When depressed at a second stroke, the middle downward sloping portion 2h of the push button 2a is brought into contact with the upward sloping portion 9f of the small movable body 9a (moved rightward) to close the contact 18b and 19b thereof. When depressed at a third stroke, the short downward sloping portion 2d of the push button 2a is brought into contact with the upward sloping portion 9f of the small movable body 9b (moved rightward) to close the contacts 18c and 19c thereof. Under these conditions, the interlock contacts 18d and 19d of the large movable body 10b are kept closed. 
     In the same way, when the push button 2b is depressed at a first stroke, the long downward sloping portion 2i of the push button 2b (projecting from the gap 1f) is brought into contact with the upward sloping portion 10f of the large movable body 10b (moved rightward) to close the contacts 18a and 19a and open the interlock contacts 18d and 19d thereof. When depressed at a second stroke, the middle downward sloping portion 2h of the push button 2b is brought into contact with the upward sloping portion 9f of the small movable body 9c (moved leftward) to close the contact 18b and 19b thereof; and when depressed at a third stroke, the short downward sloping portion 2d of the push button 2b is brought into contact with the upward sloping portion 9f of the small movable body 9d (moved leftward) to close the contacts 18c and 19c thereof. Under these conditions, the interlock contacts 18d and 19d of the large movable body 10a are kept closed. 
     In the above-mentioned construction of the push button switch provided with the multistage actuation interlock function according to the present invention, since the interlock plate 7 formed with two right and left symmetrical axle portions 7a and 7b engaged with the two engaging portions 2g of the push buttons 2a and 2b supported in an upward direction by the two return springs 8a and 8b (without supporting the interlock plate by the two upper and lower return springs as with the case of the prior art), it is possible to minimize the size of the interlock mechanism. In addition, since the movable bodies having the movable contacts are moved in the horizontal direction (without moving in the vertical direction as with the case of the prior art), it is possible to further reduce the entire size of the push button switch. 
     FIG. 6 shows an external wiring diagram showing an example of the application of the contact outputs of the push button switch PBS according to the present invention. 
     By use of the push button PBS, the following six magnetic contacts MC can be selectively energized: a first magnetic contact MC1 (the first stage speed in the normal direction), a second magnetic contact MC2 (the second stage speed in the normal direction), a third magnetic contact MC3 (the third stage speed in the normal direction), a fourth magnetic contact MC4 (the first stage speed in the reverse direction), a fifth magnetic contact MC5 (the second stage speed in the reverse direction), and a sixth magnetic contact MC6 (the third stage speed in the reverse direction). 
     The electrical interlock function can be realized on the basis of the normally-closed contacts in the reversible operation, for instance as follows: when the first stage speed normal direction push button is depressed, since the normally-open contacts T1-T2 on the normal direction side are turned on, the first contact MC1 can be energized by way of a power source PS, the normally-closed contacts T17-T18 on the reverse direction side, the normally-open contacts T1-T2 (now closed) on the normal direction side, the normally-closed contact Ic31 of the third stage speed normal direction contact MC3, and the normally-closed contact Ic2 of the second stage speed normal direction contact MC2. In the same way, when the second stage speed normal direction push button is depressed, since the normal-open contacts T3-T4 on the normal direction side are turned on, the second contact MC2 can be energized by way of the power source PS, the normally-closed contacts T17-T18 on the reverse side, the normal-open contacts T3-T4 (now closed) on the normal direction side, and the normally-closed contact Ic32 of the third stage speed normal direction contact MC3. In the same way, when the third stage speed normal direction push button is depressed, since the normal-open contacts T5-T6 on the normal direction side are turned on, the third contact MC3 can be energized by way of the power source PS, the normally-closed contacts T17-T1B on the reverse direction side, and the normally-open contacts T5-T6 (now closed) on the normal direction side. 
     Further, when the first stage speed reverse direction push button is depressed, since the normally-open contacts T11-T12 on the reverse direction side are turned on, the fourth contact MC4 can be energized by way of a power source PS, the normally-closed contacts T7-T8 on the normal direction side, the normal-open contacts T11-T12 (now closed) on the reverse direction side, the normally-closed contact Ic61 of the third stage speed reverse direction contact MC6, and the normally-closed contact Ic5 of the second stage speed reverse direction contact MC5. In the same way, when the second stage speed reverse direction push button is depressed, since the normally-open contacts T13-T14 on the reverse direction side are turned on, the fifth contact MC5 can be energized by way of the power source PS, the normally-closed contacts T7-T8 on the normal direction side, the normal-open contacts T13-T14 (now closed) on the reverse direction side, and the normally-closed contact Ic62 of the third stage speed reverse direction contact MC6. In the same way, when the third stage speed reverse direction push button is depressed, since the normally-open contacts T15-T16 on the reverse direction side are turned on, the sixth contact MC6 can be energized by way of the power source PS, the normally-closed contacts T7-T8 on the normal direction side, and the normal-open contacts T15-T16 (now closed) on the reverse direction side. 
     In the above-mentioned case, as shown in FIG. 7, the normally-open contact terminal T1 and the normally-closed contract terminal T17 can be connected easily by use of a connection plate 15a, because the two terminals T1 and T17 are arranged side by side. In the prior art push button, since the movable bodies are arranged in the casing and the fixed bodies are arranged on the base, separately, it has been necessary to use an extension wire to connect these terminals. In the present invention, however, since the movable bodies are moved only in the horizontal direction, it is possible to simplify the electrical interlock operation through the normally-closed contacts. 
     With reference to FIG. 4, the case where the push button switch according to the present invention is applied to the switch for driving a motor at three stage speeds in both the normal and reverse directions will be explained. The arrangements of the respective movable contacts are now explained. In FIG. 4, the inside of the casing 1 is divided into the right side (e.g., normal direction side) and the left side (e.g., reverse direction side) by the two opposing projection walls 11. On the right half (the normal direction) side, the lower left side is the first stage speed normally-open contacts 18a and 19a (only the movable contact numeral 18a is shown but the fixed contact numeral 19a is omitted); the lower right sides is the second stage speed normally-open contact 18b and 19b. The upper right side is the third stage speed normally-open contact 18c and 19c; and the upper left sides is the electrical interlock normally-closed contact 18d and 19d. 
     Further, on the left half (the reverse direction) side, the upper right side is the first stage speed normally-open contact 18a and 19a. The upper left side is the second stage speed normally-open contact 18b and 19a; the lower left side is the third stage speed normally-open contact 18c and 19c; and the lower right side is the electrical interlock normally-closed contact 18d and 19d. In the construction as described above, the second and third stage speed normal open contacts 18b and 18c are both arranged in the lateral direction on both the right half of the normal direction contacts and the left half of the reverse direction contacts. 
     With reference to FIGS. 8(A) to 8(D), the open-closed conditions of the respective movable contacts when The normal direction push button 2a is depressed deeply in sequence will be explained. When the push button 2a is not depressed as shown in FIG. 8(A), the first-, second- and third-stage speed normal direction normally-open contacts 18a, 18b and 18c are all turned off. On the other hand, only the interlock normally-closed contact 18d is turned on to interlock the reverse direction contact circuit. When the push button 2a is depressed to a first depth as shown in FIG. 8(B), only the first stage speed normal direction normally-open contact 18a is turned on (by the downward sloping portion 2i shown in FIG. 5). The second- and third stage speed normal direction normally-open contacts 18b and 18c are turned off; and the interlock normally-closed contact 18d is turned off. When the push button 2a is further depressed to a second depth as shown in FIG. 8(C), the second stage speed normal direction normally-open contact 18b is additionally turned on (by the downward sloping portion 2h shown in FIG. 5); and when the push button 2a is further depressed to a third depth as shown in FIG. 8(D), the third speed normal direction normally-open contact 18c (not shown in FIG. 8(D)) is additionally turned on (by the downward sloping portion 2d shown in FIG. 5). As described above, since the movable bodies 10 are moved in the direction perpendicular to the movement direction of the push button, it is possible to realize a multistage operation by utilizing a narrow space effectively. 
     With reference to FIGS. 9(A) to 9(F), the movement of the interlock plate 7 and the movable normally-open contacts obtained when the push button 2a is depressed will be explained, in which FIGS. 9(A), 9(C) and 9(E) show the movement of the interlock plate 7 and FIGS. 9(B), 9(D) and 9(F) show the movement of the normally-open contacts (because the interlock plate 7 and the movable normally-open contacts are not arranged on the same plane). 
     FIG. 9(A) shows the state where the push button 2a is not depressed. FIG. 9(C) shows the state where the left side push button 2b is depressed slightly and the right side push button 2a is pushed so that the movable contact 18a is brought into contact with the fixed contact 19a. Under these conditions, the lower side portion of the interlock plate 7 is in contact with the left side of the lower projection 5 (to provide an interlock effect). FIG. 9(E) shows the state where the right side push button 2a is further depressed to further shift the projection portion 5 of the interlock plate 5 under the condition that the normally-open contacts 18a and 19a are kept in contact with each other. In this case, the axle portion 7a of the interlock plate 7 slides in the engaging portion 2g of the push button 2a in the horizontal direction. Since the fulcrum of the interlock plate 7 is not fixed, it is possible to construct the multistage push button switch provided with a multistage actuation interlock function in a narrow space.