An output terminal and a wiring terminal
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XIAMEN FULANG ELECTRONICS
- Filing Date
- 2025-07-24
- Publication Date
- 2026-07-14
Smart Images

Figure CN224502393U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of terminal blocks, and more particularly to an output terminal block and a wiring terminal block. Background Technology
[0002] Terminal blocks are accessories used to achieve electrical connections. They serve to connect wires and cables in electronic devices, circuit boards, or electrical systems, facilitating electrical connections.
[0003] In related technologies, terminal blocks include input terminals and output terminals. When the housing of an input terminal is inserted into the housing of an output terminal, each output conductive piece of the output terminal is inserted into the corresponding input conductive piece of the corresponding input terminal, so as to realize the connection between each input port of the input terminal and each output port of the output terminal.
[0004] In practical applications, in order to meet certain circuit functions, one input port corresponds to two output ports, and they are connected to each output conductive plate through a PCB board so that the two output ports corresponding to each input port are relatively dispersed. This design results in high production costs for the terminal blocks, so it needs to be improved. Summary of the Invention
[0005] In order to satisfy the requirement that the two output ports corresponding to each input port are relatively dispersed, and at the same time reduce the production cost of the terminal block, the present application provides an output terminal.
[0006] The output terminal provided in this application adopts the following technical solution:
[0007] An output terminal includes a mounting housing, a plurality of first output conductive sheets, a plurality of second output conductive sheets, and a plurality of connecting conductive plates; the plurality of first output conductive sheets and the plurality of second output conductive sheets are spaced apart and staggered along a first direction; both ends of each connecting conductive plate pass through the mounting housing and are respectively connected to opposite first output conductive sheets and second output conductive sheets; wherein, at least one of the connecting conductive plates has both ends connected to non-adjacent first output conductive sheets and second output conductive sheets.
[0008] By adopting the above technical solution, in practical applications, one of the connecting conductive plates realizes the connection between one of the first output conductive plates and one of the second output conductive plates, so as to realize the connection between one input port and two output ports. Since the two ends of at least one connecting conductive plate are connected to the non-adjacent first output conductive plate and second output conductive plate, the two output ports corresponding to each input port are relatively dispersed. The structure of the connecting conductive plate is simple and the production cost is low, which can effectively reduce the production cost of the terminal block.
[0009] Preferably, the mounting housing includes multiple mounting bodies and mounting bases, the multiple mounting bodies are spaced apart along the first direction and adjacent two mounting bodies are fixed by snap-fit, and the mounting base is snap-fitted to the multiple mounting bodies.
[0010] By adopting the above technical solution and setting up multiple mounting bodies and mounting bases, the assembly of the mounting shell can be facilitated.
[0011] Preferably, the mounting body has a first snap-fit groove and a second snap-fit groove spaced apart along the second direction on one side. The mounting base includes a base body, a plurality of snap-fit blocks and a plurality of snap-fit plates. The plurality of snap-fit blocks and the plurality of snap-fit plates are disposed on the base body, and each snap-fit block snaps into each of the first snap-fit grooves, and each snap-fit plate snaps into each of the second snap-fit grooves.
[0012] By adopting the above technical solution, the first and second snap-fit slots are spaced apart along the second direction, so that each snap-fit block snaps into each first snap-fit slot and each snap-fit plate snaps into each second snap-fit slot, thereby realizing the snap-fit between the mounting base and the mounting body and ensuring the stability of the snap-fit between the mounting base and the mounting body.
[0013] Preferably, the mounting body has a positioning rib on the side near the mounting base, and the mounting base has a positioning groove, into which the positioning rib is inserted.
[0014] By adopting the above technical solution, and by setting positioning ribs and positioning grooves, the positioning ribs are inserted into the positioning grooves to achieve positioning installation between the installation body and the mounting base, while ensuring a safe distance between the installation body and the mounting base.
[0015] Preferably, the mounting body has a recessed groove, one end of the first output conductive sheet or the second output conductive sheet is embedded in the recessed groove, and the other end passes through the mounting body, and the wiring surface of the first output conductive sheet or the second output conductive sheet is slightly higher than the bottom wall of the inlet hole of the mounting body.
[0016] By adopting the above technical solution, the first output conductive sheet or the second output conductive sheet is embedded in the groove by setting the groove, so as to realize the installation and fixation of the first output conductive sheet or the second output conductive sheet. The wiring surface of the first output conductive sheet or the second output conductive sheet is slightly higher than the bottom wall of the inlet hole of the mounting body, so that the wire can be pressed more stably and firmly onto the first output conductive sheet or the second output conductive sheet.
[0017] Preferably, the mounting body has a limiting groove, the limiting groove is connected to the recess, and the end of the first output conductive sheet near the inlet hole is bent and snapped into the limiting groove.
[0018] By adopting the above technical solution and setting a limiting groove, the stability of the first output conductive sheet being installed and fixed to the mounting body is improved.
[0019] Preferably, both the first output conductive sheet and the second output conductive sheet have connection holes, and the end of the connecting conductive plate is snapped into the connection hole.
[0020] By adopting the above technical solution, and by setting a connection hole, the connecting conductive plate can be snapped onto the first output conductive sheet or the second output conductive sheet, thereby facilitating the connection between the connecting conductive plate and the first output conductive sheet or the second output conductive sheet.
[0021] Preferably, the end of the connecting conductive plate is provided with a deformation groove to form two snap-fit pieces, which are elastically snapped into the connecting hole.
[0022] By adopting the above technical solution, by setting a deformation groove to form two snap-fit pieces, the snap-fit pieces cooperate with the connection hole to realize the snap-fit of the conductive plate. Under the action of the deformation groove, it is easy to apply force to the snap-fit pieces, so that the two snap-fit pieces deform towards the side that is closer to each other, thereby facilitating the snap-fit of the two snap-fit pieces into the connection hole and facilitating the detachment of the two snap-fit pieces from the connection hole.
[0023] Preferably, the distance between the two snap-fit pieces on the opposite side is greater than the length of the connecting hole, the lower ends of the two snap-fit pieces are provided with abutment blocks, and the distance between the two abutment blocks on the opposite side is less than the difference between the distance between the two snap-fit pieces on the opposite side and the length of the connecting hole.
[0024] By adopting the above technical solution, when the two snap-fit pieces are inserted into the connection hole, the two snap-fit pieces, under the action of elasticity, make the two abutment blocks press against each other to ensure the interference fit between the connecting conductive plate and the first output conductive piece or the second output conductive piece, thereby ensuring the stability and reliability of the snap-fit between the two snap-fit pieces and the connection hole.
[0025] Secondly, this application provides a terminal block.
[0026] The terminal block provided in this application adopts the following technical solution:
[0027] A terminal block comprising the output terminal described above.
[0028] In summary, this application includes at least one of the following beneficial technical effects:
[0029] 1. In practical applications, one of the connecting conductive plates realizes the connection between one of the first output conductive plates and one of the second output conductive plates, so as to realize the connection between one input port and two output ports. Since at least one of the connecting conductive plates is connected to the two non-adjacent first output conductive plates and second output conductive plates, the two output ports corresponding to each input port are relatively dispersed. The structure of the connecting conductive plate is simple and the production cost is low, which can effectively reduce the production cost of the terminal block.
[0030] 2. By setting a groove, the first output conductive sheet or the second output conductive sheet is embedded in the groove to realize the installation and fixation of the first output conductive sheet or the second output conductive sheet. The wiring surface of the first output conductive sheet or the second output conductive sheet is slightly higher than the bottom wall of the inlet hole of the mounting body, so that the wire can be pressed more stably and firmly onto the first output conductive sheet or the second output conductive sheet.
[0031] 3. When the two snap-fit pieces are inserted into the connection hole, the two snap-fit pieces, under the action of elasticity, make the two abutment blocks press against each other to ensure the interference fit between the connecting conductive plate and the first output conductive piece or the second output conductive piece, thereby ensuring the stability and reliability of the snap-fit between the two snap-fit pieces and the connection hole. Attached Figure Description
[0032] Figure 1 This is a schematic diagram of the overall structure of the wiring terminal in Embodiment 1 of this application;
[0033] Figure 2 This is a schematic diagram of the internal structure of the wiring terminal in Embodiment 1 of this application;
[0034] Figure 3 This is an exploded view of the terminal block structure in Embodiment 1 of this application;
[0035] Figure 4 This is an exploded view of the output terminal structure in Embodiment 1 of this application;
[0036] Figure 5 This is a schematic diagram of the output terminal portion structure in Embodiment 1 of this application;
[0037] Figure 6 This is a schematic diagram of the external structure of the output terminal in Embodiment 1 of this application;
[0038] Figure 7 This is an exploded view of the output terminal portion in Embodiment 1 of this application;
[0039] Figure 8 This is a schematic diagram of the internal structure of the output terminal in Embodiment 1 of this application;
[0040] Figure 9 This is a schematic diagram of the conductive plate mounting structure in Embodiment 1 of this application;
[0041] Figure 10 This is a schematic diagram of the overall structure of the output terminal in Embodiment 1 of this application;
[0042] Figure 11 This is a schematic diagram of the output terminal portion structure in Embodiment 2 of this application;
[0043] Figure 12 This is a schematic diagram of the overall structure of the connecting conductive plate in Embodiment 2 of this application.
[0044] Reference numerals: 1. Input terminal; 11. Plug-in housing; 12. Input conductive sheet; 13. Input port; 131. Input button; 132. Input pressure plate; 14. Anti-misoperation protrusion; 2. Output terminal; 21. Mounting housing; 211. Mounting body; 211a. First snap-fit groove; 211b. Second snap-fit groove; 211c. Positioning rib; 211d. Embedded groove; 211e. Cable inlet hole; 211f. Limiting groove; 212. Mounting base; 212a, base; 212b, snap-fit block; 212c, snap-fit plate; 212d, positioning groove; 212e, alignment hole; 212f, support rib; 212g, test hole; 22, first output conductive sheet; 23, second output conductive sheet; 24, connecting conductive plate; 241, deformation groove; 242, snap-fit piece; 243, abutting block; 25, output port; 251, output button; 252, output pressure plate; 26, connecting hole. Detailed Implementation
[0045] The following is in conjunction with the appendix Figure 1-10 This application will be described in further detail.
[0046] This application discloses a terminal block.
[0047] Example 1:
[0048] Reference Figure 1 and Figure 2 The terminal block includes an input terminal 1 and an output terminal 2. The input terminal 1 includes a plug-in housing 11, multiple input conductive plates 12, and multiple input ports 13. The multiple input conductive plates 12 are fixedly connected in the plug-in housing 11 and are evenly spaced along a first direction. The first direction is... Figure 1 In the X-axis direction, each input port 13 is matched with each input conductive plate 12. Specifically, the input port 13 includes an input button 131 and an input pressure plate 132. The wire passes through the plug-in housing 11. By rotating the input button 131, the input pressure plate 132 abuts against the wire, so that the wire is pressed between the input pressure plate 132 and the input conductive plate 12.
[0049] Reference Figure 2 and Figure 3The output terminal 2 includes a mounting shell 21, multiple first output conductive sheets 22, multiple second output conductive sheets 23, multiple connecting conductive plates 24, and multiple output ports 25. The shape of the mounting shell 21 is adapted to the plug-in shell 11, allowing the plug-in shell 11 to be inserted into the mounting shell 21. The mounting shell 21 has multiple anti-misalignment slots (not shown in the figure), and correspondingly, the plug-in shell 11 has multiple anti-misalignment protrusions 14. Each anti-misalignment protrusion 14 is inserted into its respective anti-misalignment slot, facilitating accurate insertion between the plug-in shell 11 and the mounting shell 21. In this embodiment, the number of first output conductive sheets 22, second output conductive sheets 23, connecting conductive plates 24, and input conductive sheets 12 is the same, and the number of output ports 25 is the sum of the number of first output conductive sheets 22 and second output conductive sheets 23.
[0050] Reference Figure 3 and Figure 4 Multiple first output conductive plates 22 and multiple second output conductive plates 23 are fixedly connected in the mounting housing 21. The multiple first output conductive plates 22 are evenly spaced along a first direction, and the multiple second output conductive plates 23 are also evenly spaced along the first direction. The multiple first output conductive plates 22 and multiple second output conductive plates 23 are staggered, that is, the first output conductive plates 22 and the second output conductive plates 23 are arranged sequentially along the first direction. The length of the second output conductive plate 23 is less than the length of the first output conductive plate 22.
[0051] Both ends of each connecting conductive plate 24 pass through the mounting shell 21 and are respectively connected to each first output conductive sheet 22 and each second output conductive sheet 23, that is, one connecting conductive plate 24 corresponds to one first output conductive sheet 22 and one second output conductive sheet 23. Among them, at least one connecting conductive plate 24 is connected at both ends to a non-adjacent first output conductive sheet 22 and second output conductive sheet 23.
[0052] Each output port 25 corresponds one-to-one with each first output conductive sheet 22 and each second output conductive sheet 23. Specifically, each output port 25 includes an output button 251 and an output pressure plate 252. The wire is passed through the mounting housing 21. By rotating the output button 251, the output pressure plate 252 abuts against the wire, so that the wire is pressed between the output pressure plate 252 and the first output conductive sheet 22 or the second output conductive sheet 23.
[0053] In practical applications, the plug-in housing 11 is plugged into the mounting housing 21, so that each input conductive piece 12 is connected to each first output conductive piece 22. The connecting conductive plate 24 replaces the PCB board to realize the connection between the first output conductive piece 22 and the second output conductive piece 23, so that one input port 13 is connected to two output ports 25. Since at least one end of the connecting conductive plate 24 is connected to the non-adjacent first output conductive piece 22 and the second output conductive piece 23, the two output ports 25 corresponding to each input port 13 are relatively dispersed. Moreover, the structure of the connecting conductive plate 24 is simple and the production cost is low, which can effectively reduce the production cost of the terminal block.
[0054] Reference Figure 4 and Figure 5 In some embodiments, the mounting housing 21 includes multiple mounting bodies 211 and mounting bases 212. The multiple mounting bodies 211 are spaced apart along a first direction, and two adjacent mounting bodies 211 are snapped together by a protrusion and groove structure. The number of mounting bodies 211 is the same as the number of output ports 25, and each output port 25 is mounted on its respective mounting body 211. Each first output conductive sheet 22 and each second output conductive sheet 23 are fixedly connected to the mounting body 211. The mounting base 212 is snapped onto the multiple mounting bodies 211, and each connecting conductive plate 24 passes through the mounting base 212. When assembling the mounting housing 21, the multiple mounting bodies 211 are first snapped together, and then the mounting base 212 is snapped onto the multiple mounting bodies 211. This operation is simple and convenient, facilitating the assembly of the mounting housing 21. Simultaneously, it facilitates the installation of the output ports 25 into the mounting bodies 211.
[0055] Reference Figure 5 In some embodiments, the mounting body 211 has a first snap-fit groove 211a and a second snap-fit groove 211b spaced apart along a second direction on the side near the mounting base 212, wherein the second direction is... Figure 1The Y-axis direction is shown in the figure. Meanwhile, the mounting base 212 includes a base body 212a, multiple snap-fit blocks 212b, and multiple snap-fit plates 212c. The multiple snap-fit blocks 212b and multiple snap-fit plates 212c are integrally connected to the side of the base body 212a near the mounting body 211. The number of snap-fit blocks 212b is half the number of mounting bodies 211, and the number of snap-fit plates 212c is the same as the number of mounting bodies 211. Using the protrusions on opposite sides of the snap-fit blocks 212b and snap-fit plates 212c, each snap-fit block 212b snaps into its corresponding first snap-fit groove 211a, and each snap-fit plate 212c snaps into its corresponding second snap-fit groove 211b, thereby achieving the snap-fit connection between the mounting base 212 and the mounting body 211 and ensuring the stability of the snap-fit connection between the mounting base 212 and the mounting body 211. It should be noted that the structure of the plug-in shell 11 is similar to that of the mounting shell 21, which allows the mounting body 211 of the mounting shell 21 to be used in the plug-in shell 11. This eliminates the need for different molds to be used in the production of this part of the plug-in shell 11, thus effectively reducing production costs.
[0056] Reference Figure 5 and Figure 6 In some embodiments, a rectangular plate-shaped positioning rib 211c protrudes from the side of the mounting body 211 near the base 212a, and a corresponding positioning groove 212d is provided on the base 212a. The positioning rib 211c is inserted into the positioning groove 212d to realize the positioning installation between the mounting body 211 and the mounting base 212, thereby facilitating the accurate assembly of the mounting shell 21 and ensuring a safe distance between the mounting body 211 and the mounting base 212.
[0057] Reference Figure 5 and Figure 7 In some embodiments, the mounting body 211 has a groove 211d, in which the first output conductive sheet 22 or the second output conductive sheet 23 is embedded. One end of the first output conductive sheet 22 or the second output conductive sheet 23 is embedded in the groove 211d, and the other end passes through the mounting body 211, so as to realize the installation and fixation of the first output conductive sheet 22 or the second output conductive sheet 23. The mounting body 211 has an inlet hole 211e for the power supply wire to pass through on the side away from the plug shell 11. The wiring surface of the first output conductive plate 22 or the second output conductive plate 23 (i.e., the upper side of the first output conductive plate 22 or the second output conductive plate 23) is slightly higher than the bottom wall of the inlet hole 211e. The insulation layer of the wire abuts against the end of the first output conductive plate 22 or the second output conductive plate 23, so that the wire conduction is more fully abutted against the wiring surface, thereby making the wire more stable and firm to be pressed against the first output conductive plate 22 or the second output conductive plate 23, so as to improve the stability of the output terminal 2.
[0058] In some embodiments, the base 212a has alignment holes 212e corresponding to the number of first output conductive pieces 22. When the mounting base 212 is snapped onto multiple mounting bodies 211, each first output conductive piece 22 passes through each alignment hole 212e to achieve error-proof assembly of the mounting shell 21. Simultaneously, multiple support ribs 212f protrude from the base 212a, and each first output conductive piece 22 and each second output conductive piece 23 abut against each support rib 212f to improve installation stability.
[0059] Reference Figure 5 and Figure 6 In some embodiments, the base 212a is also provided with a plurality of test holes 212g, each test hole 212g being connected to each second output conductive sheet 23, so as to detect the operation of the second output conductive sheet 23 and detect whether the connecting conductive plate 24 connects the first output conductive sheet 22 and the second output conductive sheet 23.
[0060] Reference Figure 8 In some embodiments, the mounting body 211 has a limiting groove 211f, which is connected to the recessed groove 211d. The end of the first output conductive sheet 22 near the inlet hole 211e is bent and confined in the limiting groove 211f to improve the stability of the first output conductive sheet 22 in the mounting body 211. At the same time, due to the bending of the first output conductive sheet 22, the end of the first output conductive sheet 22 near the inlet hole 211e forms a rounded corner, so that it does not affect the wire inlet.
[0061] Reference Figure 9 In some embodiments, both the first output conductive sheet 22 and the second output conductive sheet 23 are provided with rectangular connection holes 26, and the end of the connecting conductive plate 24 is snapped into the connection hole 26, thereby facilitating the connection between the connecting conductive plate 24 and the first output conductive sheet 22 or the second output conductive sheet 23.
[0062] A deformation groove 241 is provided at the middle of the end of the connecting conductive plate 24 to form two snap-fit pieces 242. The two snap-fit pieces 242 are elastically snapped into the connecting hole 26 to achieve snap-fit of the connecting conductive plate 24. Under the action of the deformation groove 241, it is easy to apply force to the snap-fit pieces 242, causing the two snap-fit pieces 242 to deform towards each other, thereby facilitating the disengagement of the two snap-fit pieces 242 from the connecting hole 26. At the same time, the deformation of the two snap-fit pieces 242 also facilitates their snap-fit into the connecting hole 26, thus facilitating the installation and removal of the connecting conductive plate 24.
[0063] In some embodiments, the distance between the two snap-fit pieces 242 on the opposite side is 'a', the length of the connecting hole 26 is 'b', and 'a' > 'b'. Simultaneously, the lower ends of both snap-fit pieces 242 are bent inwards to form abutment blocks 243, and the distance between the two abutment blocks 243 on the opposite side is 'c', and 'ab' > 'c'. In this embodiment, 'a' = 2.8, 'b' = 2, and 'c' = 0.8. With this configuration, when the two snap-fit pieces 242 are inserted into the connecting hole 26, the two snap-fit pieces 242, under elastic action, cause the two abutment blocks 243 to press against each other, ensuring an interference fit between the connecting conductive plate 24 and the first output conductive piece 22 or the second output conductive piece 23, thereby ensuring the stability and reliability of the snap-fit connection between the two snap-fit pieces 242 and the connecting hole 26.
[0064] In some embodiments, multiple connecting conductive plates 24 are configured with different sizes and are located on the same straight line. This embodiment takes three connecting conductive plates 24 as an example. The largest connecting conductive plate 24 is connected to the outermost first output conductive sheet 22 and second output conductive sheet 23, and the smallest connecting conductive plate 24 is connected to the innermost first output conductive sheet 22 and second output conductive sheet 23, so as to reduce the space occupied by multiple connecting conductive plates 24, thereby ensuring that the overall size of the output terminal 2 is small.
[0065] Reference Figure 10 In some embodiments, there are two connection holes 26 for each first output conductive sheet 22 and each second output conductive sheet 23. This allows multiple connecting conductive plates 24 to be staggered. By using connecting conductive plates 24 of different lengths in conjunction with different first output conductive sheets 22 and second output conductive sheets 23, the two output ports 25 corresponding to the input port 13 can be changed to meet different circuit functions.
[0066] The implementation principle of this embodiment is as follows: In practical applications, the plug-in shell 11 is plugged into the mounting shell 21, so that each input conductive sheet 12 is connected to each first output conductive sheet 22. The connecting conductive plate 24 replaces the PCB board to realize the connection between the first output conductive sheet 22 and the second output conductive sheet 23, so that one input port 13 is connected to two output ports 25. Since at least one connecting conductive plate 24 is connected to the two ends of the non-adjacent first output conductive sheet 22 and the second output conductive sheet 23, it satisfies that the two output ports 25 corresponding to each input port 13 are relatively dispersed. Moreover, the structure of the connecting conductive plate 24 is simple and the production cost is low, which can effectively reduce the production cost of the terminal block.
[0067] Example 2:
[0068] Reference Figure 11This embodiment is identical to Embodiment 1 in all other structural aspects, except that there are three first output conductive sheets 22 and two second output conductive sheets 23, and two connecting conductive plates 24. The two conductive plates 24 connect the two first output conductive sheets 22 and the two second output conductive sheets 23. The innermost first output conductive sheet 22 and second output conductive sheet 23 are integrally connected, thus reducing the number of connecting conductive plates 24 and further reducing the production cost of the output terminal 2. Of course, in other embodiments, such as... Figure 12 As shown, the connecting conductive plate 24 has three plug-in ports, which enables one input port 13 to be connected to three output ports 25.
[0069] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. An output terminal, characterized in that, It includes a mounting shell (21), a plurality of first output conductive sheets (22), a plurality of second output conductive sheets (23), and a plurality of connecting conductive plates (24); the plurality of first output conductive sheets (22) and the plurality of second output conductive sheets (23) are spaced apart and staggered along a first direction; both ends of each connecting conductive plate (24) are inserted through the mounting shell (21) and respectively connected to the corresponding first output conductive sheet (22) and second output conductive sheet (23); wherein, at least one of the connecting conductive plates (24) is connected at both ends to non-adjacent first output conductive sheets (22) and second output conductive sheets (23).
2. An output terminal according to claim 1, characterized in that, The mounting housing (21) includes multiple mounting bodies (211) and mounting bases (212). The multiple mounting bodies (211) are spaced apart along the first direction and two adjacent mounting bodies (211) are fixed by snap-fit. The mounting base (212) is snap-fitted onto the multiple mounting bodies (211).
3. An output terminal according to claim 2, characterized in that, The mounting body (211) has a first snap-fit groove (211a) and a second snap-fit groove (211b) spaced apart along a second direction on one side. The mounting base (212) includes a base body (212a), a plurality of snap-fit blocks (212b) and a plurality of snap-fit plates (212c). The plurality of snap-fit blocks (212b) and the plurality of snap-fit plates (212c) are disposed on the base body (212a), and each snap-fit block (212b) snaps into each of the first snap-fit grooves (211a), and each snap-fit plate (212c) snaps into each of the second snap-fit grooves (211b).
4. An output terminal according to claim 2, characterized in that, The mounting body (211) has a positioning rib (211c) on the side near the mounting base (212), and the mounting base (212) has a positioning groove (212d), and the positioning rib (211c) is inserted into the positioning groove (212d).
5. An output terminal according to claim 2, characterized in that, The mounting body (211) has a groove (211d), one end of the first output conductive sheet (22) or the second output conductive sheet (23) is embedded in the groove (211d), and the other end passes through the mounting body (211). The wiring surface of the first output conductive sheet (22) or the second output conductive sheet (23) is slightly higher than the bottom wall of the inlet hole (211e) of the mounting body (211).
6. An output terminal according to claim 5, characterized in that, The mounting body (211) has a limiting groove (211f), which is connected to the recess (211d). The first output conductive sheet (22) is bent at one end near the inlet hole (211e) and snapped into the limiting groove (211f).
7. An output terminal according to claim 1, characterized in that, Both the first output conductive sheet (22) and the second output conductive sheet (23) are provided with connection holes (26), and the end of the connecting conductive plate (24) is located in the connection hole (26).
8. An output terminal according to claim 7, characterized in that, The end of the connecting conductive plate (24) is provided with a deformation groove (241) to form two snap-fit pieces (242), which are elastically snapped into the connecting hole (26).
9. An output terminal according to claim 8, characterized in that, The distance between the two snap-fit pieces (242) on the side away from each other is greater than the length of the connecting hole (26). The lower ends of the two snap-fit pieces (242) are provided with abutment blocks (243), and the distance between the two abutment blocks (243) on the side close to each other is less than the difference between the distance between the two snap-fit pieces (242) on the side away from each other and the length of the connecting hole (26).
10. A terminal block, characterized in that, Includes the output terminal (2) as described in any one of claims 1-9.