TWI626127B - Detachable joint processing cassette and clamp tool using the same - Google Patents

Abstract

A joint processing cassette is detachably assembled in a tool body, wherein the tool body includes an accommodating portion and a driving portion, a movement direction of the driving portion defines a first axis, and the joint processing cassette includes a body And a processing block. The body is detachably disposed in the accommodating portion and has a processing opening therein. The processing block is slidably disposed in the body along the first axis and has a connecting portion for detachably engaging with the driving portion of the tool body, so that the connecting portion is driven by the driving portion. The processing block is slid relative to the processing opening along the first axis.

Description

Detachable joint processing cassette and clamp tool using same

The present invention relates to a joint processing cassette and a clamp tool using the same, and particularly to a detachable joint processing cassette for processing a cable joint and a clamp tool using the same.

At present, cables are commonly used for signal transmission. For example, the transmission lines used to transmit signals such as video, sound, and data in televisions, telephones, and computer equipment are cables. In order to facilitate the connection of the cable to the required equipment, a connector is usually connected to the end of the cable, such as a network cable connector (RJ-45) of a computer device or a general telephone line connector (RJ-11). The connection of these connectors to the cable is usually fixed to the cable connector with a specific crimping tool to form a cable terminal connector. Therefore, crimping tools for cables of various specifications are currently on the market, such as US Patent Publication No. 5,941,120, which discloses the related structural design of crimping tools for cables. In addition, the Republic of China Patent Bulletin No. 534510 discloses a composite cable connector crimping tool capable of cutting, peeling off the insulation layer and crimping the cable. However, the disclosure technique requires cutting off the cable, peeling off the insulation layer, and crimping at different parts of the tool separately. In addition to being inconvenient, the overall size of the cable connector crimping tool disclosed by the cable connector is too large to carry. On the other hand, when crimping cables of different specifications, the operator needs to prepare crimping tools of various specifications to be applicable to a variety of cable connectors of different specific specifications at the same time. Therefore, in order to respond to the connection and fixing of various types of cable connectors and cables, operators must prepare various special crimping tools in advance to complete it. This will undoubtedly increase the work and The trouble of carrying, and the cost of purchasing tools is relatively high. Therefore, how to design a clamp tool suitable for different specifications of cables and suitable for various processing operations is an important subject to meet the convenient needs of operators in use, carrying and operation.

The purpose of the present invention is to provide a detachable joint processing cassette and a clamp tool using the same, which can be applied to cables of different specifications and various processing operations to meet the needs of operators in use, carrying and operation. To achieve the above object, an embodiment of the present invention provides a joint processing cassette detachably assembled to a tool body, wherein the tool body includes a receiving portion and a driving portion, and a movement direction of the driving portion defines a first A shaft, the joint processing cassette includes a body and a processing block. The body is detachably disposed in the accommodating portion, and the body has a processing opening therein. The processing block is slidably disposed in the body along the first axis, and the processing block has a connecting portion for detachably engaging with the driving portion of the tool body, so that the connecting portion is subject to the driving portion. Driven to slide the processing block relative to the processing opening along the first axis. To achieve the above object, another embodiment of the present invention provides a clamp tool, which includes a tool body and a joint processing cassette. The tool body includes a first jaw handle, a second jaw handle, an accommodating portion, and a driving portion. The second jaw handle is pivotally connected to the first jaw handle and is rotatable relative to the first jaw handle. The accommodating part is connected with the first clamp handle. The driving part is connected with the second caliper handle and is driven by the second caliper handle, and a movement direction of the driving part defines a first axis. The joint processing cassette includes a body and a processing block. The body is detachably disposed in the accommodating portion, and the body has a processing opening therein. The processing block is slidably disposed in the body along the first axis, and the processing block has a connecting portion for detachably engaging with the driving portion of the tool body, so that the connecting portion is subject to the driving portion. Driven to slide the processing block relative to the processing opening along the first axis.

In order to better understand the features, contents and advantages of the present invention and the effects that can be achieved, the present invention will be described in detail with reference to the accompanying drawings, and the embodiments are described in detail below. The use of the supplementary description may not necessarily be the inevitable aspect after the implementation of the present invention, so the proportion and arrangement relationship of the attached drawings should not be interpreted and limited to the scope of rights of the present invention in actual implementation. FIG. 1A is a schematic diagram of a clamp tool in an idle position according to an embodiment of the present invention, and FIG. 1B is a schematic diagram of a working position of the clamp tool of FIG. 1A in a processing state. Please refer to FIGS. 1A and 1B. The clamp tool 10 of the present invention includes a tool body 100 and a detachable joint processing cassette 200. The tool body 100 includes a first jaw handle 110, a second jaw handle 120, an accommodation portion 130, and a driving portion 140. According to FIG. 1A, one end of the second pliers handle 120 is pivotally connected to one end of the first pliers handle 110 and can be pivoted relative to the first pliers handle 110 in a position shown in FIGS. 1A and 1B. Between rotations. The accommodating portion 130 is connected to the first pliers handle 110 and has an accommodating opening 131 for receiving the joint processing cassette 200, and the driving portion 140 is connected to the second pliers handle 120. When the second jaw handle 120 is relatively rotated toward the first jaw handle 110 (pivoted from FIG. 1A to the position of FIG. 1B), the second jaw handle 120 drives the driving part 140 to move in a moving direction (for example, an upward direction) Movement), wherein the movement direction of the driving part 140 defines the first axis L1. After the driving part 140 is driven by the second pliers handle 120, the joint processing cassette 200 can be linked to process the cables and joints. When the operator rotates the second clamp handle 120 toward the first clamp handle 110 in the pivoting direction, the driving part 140 is driven by the second clamp handle 120 to drive the joint processing cassette 200. At this time, the clamp tool 10 enters from an idle state. Processing status. 2A and 2B are structural views of the joint processing cassette of FIG. 1A, and FIGS. 3A and 3B are structural views of the other side of the joint processing cassette of FIGS. 2A and 2B. Referring to FIGS. 2A and 2B and FIGS. 3A and 3B, the joint processing cassette 200 includes a body 210 and a processing block 220. The main body 210 includes a sliding groove 212 disposed in the main body 210 along the first axis L1. Therefore, the processing block 220 is slidably disposed in the sliding groove 212 of the main body 210 along the first axis L1. The joint processing cassette 200 of this embodiment is detachably mounted to the tool body 100. Therefore, when the operator wants to process different specifications of the cable connector, he can selectively assemble an appropriate joint processing cassette 200 to the tool body 100. The accommodating opening 130 of the accommodating portion 130 is used for processing the cables and connectors. In other words, the clamp tool with the detachable joint processing cassette of the present invention can be applied to the processing operations of various cable joints, reducing the operator's troubles in operation and carrying, and reducing the cost of purchasing tools. In this embodiment, the cable connector is a crystal connector (RJ-45 or RJ-11) of a network cable or a telephone line as an example, but is not limited thereto. As mentioned above, in order to make the joint processing cassette 200 detachably disposed in the tool body 100 and to drive the joint processing cassette 200 to perform a cable joint processing operation by operating the tool body 100, this embodiment is The main body 210 of the joint processing cartridge 200 is detachably disposed in the accommodating portion 130 of the tool body 100, and at the same time, the processing block 220 slidably disposed on the sliding groove 212 of the body 210 and the driving portion 140 of the tool body 100 have Linked relationships. Specifically, the processing block 220 of this embodiment is provided with a connecting portion 222 which can be detachably engaged with the driving portion 140 of the tool body 100. In this way, the connecting portion 222 can be driven by the driving portion 140 to slide the processing block 220 along the first axis L1 (as shown in FIGS. 1A and 1B). That is, when the second pliers handle 120 rotates toward the first pliers handle 110, the second pliers handle 120 will drive the driving portion 140 to drive the connecting portion 222 of the processing block 220 to move upward, thereby driving the processing block 220 along the first axis L1 direction. Slide upward to perform the processing of the cable connector, whereby the clamp tool enters the processing state from the idle position shown in FIG. 1A to the processing position shown in FIG. 1B. As a preferred embodiment, the driving portion 140 may be a driving block, the connecting portion 222 of the processing block 220 may be a card slot, and the driving portion 140 is engaged in the card slot 222. Thereby, the processing block 220 can be driven by the driving part 140 to slide back and forth in the sliding groove 212 in the direction of the first axis L1. 4A and 4B are schematic diagrams of the joint processing cassette of FIG. 2A and FIG. 2B being located at a processing position. 5A and 5B are schematic diagrams of the joint processing cassette of FIG. 3A and FIG. 3B being located at a processing position. 2A, 2B, 3A, and 3B, in order to process the cable connector, the body 210 is provided with a processing opening 214 therein. Corresponding to the processing opening 214, the processing block 220 includes at least one processing structure 224. During operation, the connecting portion 222 may be driven by the driving portion 140 to cause the processing block 220 to slide along the first axis L1 in the sliding groove 222 relative to the processing opening 214. When the processing block 220 is driven to the working position by the driving portion 140, the processing The structure 224 at least partially overlaps the processing opening 214. In this way, when the processing block 220 is driven to the working position by the driving unit 140, the processing structure 224 can process the cable connector that has been placed in the processing opening 214, such as a telephone line or a network terminal. Crimping or cutting. Further, the processing structure 224 of this embodiment includes, for example, a first processing structure 224a and a second processing structure 224b. The first processing structure 224a is a crystal joint crimping structure on one side of the body 210 (see FIG. 3A). , 3B, 5A, and 5B), the second processing structure 224b is, for example, a cutting structure located on the other side of the body 210 (as shown in FIGS. 2A, 2B, 4A, and 4B). As shown in FIGS. 4A and 4B and FIGS. 5A and 5B, in this embodiment, when the processing block 220 is driven to the working position by the driving part 140, the crystal joint crimping structure partially overlaps with one side of the processing opening 214. The cutting structure completely covers the other side of the processing opening 214. Referring to FIG. 6A and FIG. 6B, the first processing structure 224a showing the crystal joint crimping structure type of this embodiment may include two crimping structures, and the crimping operation is performed simultaneously by the two crimping structures. Among them, one pressing block structure P1 is used to press the crystal connector body, and the other pressing block structure P2 can be disposed between the pressing block structure 224a and the cutting structure 224b, and is used for crimping the electrode piece of the crystal connector to the cable. Core wire so that the two are electrically connected. Referring again to FIGS. 6A and 6B, when the processing block 220 is driven to the working position by the driving portion 140, the first processing structure 224 a showing a crystal joint crimping structure partially overlaps one side of the processing opening 214. At this time, the pressing block P1 of the first processing structure 224a that partially overlaps with the processing opening 214 will abut the crystal joint 50 in advance with a pressing structure 52 and force it to deform and deform. The pressing structure 52 after fracture deformation Part of the cable 60 is forced against the outermost insulating material of the cable 60 to fix the cable 60 into the crystal connector 50. In this way, the crystal connector 50 can be used to hold the outer layer of the cable 60 to securely fix the crystal connector 50 to the end of the cable 60. In addition, another pressing block structure P2 simultaneously pushes up the electrode sheet 54 of the crystal joint 50 to pierce the insulation of the core wire 62 of the cable 60, so that the electrode sheet 54 and the cable 60 are used to transmit signals. The respective core wires 62 are electrically connected. The second processing structure in this embodiment is a cutting blade 224b, which is used to cut off the excess cable core portion. Therefore, when the processing block 220 is driven to the working position by the driving part 140, the second processing structure 224b exhibiting a cutting structure moves along the first axis L1 until it completely covers the other side of the processing opening 214. At this time, the second processing structure 224b may The cable core 62 protruding from the crystal connector 50 shown in FIG. 6A is cut off. In a preferred embodiment, the second processing structure 224b can also cut off a protruding portion 56 of the crystal joint 50, and cut off the cable core wire 62 originally located in the protruding portion 56 (as shown in FIG. 6B, which is (Showing a schematic diagram of the protruding part of the crystal connector and the cable cut out in one embodiment of the present invention), so that the core wire of the signal transmitted in the crystal connector 50 is just flush with the cut surface. In the present invention, the position of the second processing structure 224b relative to the crystal joint 50 can be adjusted according to the part to be removed, and the present invention is not limited thereto. In addition, in order for the processing block 220 to process the cable joint in a stable operating environment, the joint processing cassette 200 must be firmly received in the receiving opening 131 of the receiving portion 130 of the tool body 100. FIG. 7A is a schematic diagram illustrating a combination of one side of a receiving portion of a tool body and a joint processing cassette in this embodiment. FIG. 7B is a schematic diagram of the combination of the other side of the accommodating part of the tool body and the joint processing cassette in this embodiment. Referring to FIG. 7A and FIG. 7B, the receiving portion 130 of the tool body 100 and the body 210 of the joint processing cassette 200 are respectively provided with a first holding portion 132 and a second holding portion 216. The second holding portion 216 is disposed on the body 210 of the joint processing cassette 200 relative to the first holding portion 132 and can be engaged with or abutted against the first holding portion 132 of the receiving portion 130 to hold the joint processing cassette 200. It is fixed in the tool body 100. It should be noted that the cooperation of the first holding portion 132 and the second holding portion 216 not only allows the joint processing cassette 200 to be stably disposed in the receiving portion 130 of the tool body 100, but also facilitates disassembly and The advantages of assembly further increase the operating efficiency of the operator. In detail, in order to make the joint processing cartridge 200 stably hold and be positioned in the accommodation opening 131 of the accommodation portion 130 of the tool body 100 and to easily disassemble the joint processing card of another joint specification from the tool body 100 For the function of the box, the second holding portion 216 includes a stop structure 216a protruding from a part of the periphery of the body 210, wherein the stop structure 216a can be on the second axis L2 perpendicular to the first axis L1 and the accommodating portion, for example. 130 abut. In addition, the second holding portion 216 may further include a first hook 216b and a second hook 216c respectively disposed on both sides of the body 210 along the first axis L1. The first hook 216b and the second hook 216c extend away from the blocking structure 216a in the direction of the second axis L2 and can be engaged with the accommodating portion 130. In a preferred embodiment, the accommodating portion 130 has a first surface 130a and a second surface 130b opposite to the first surface 130a. The blocking structure 216a abuts the first surface 130a and the first surface 130a of the accommodating portion 130. When one of the two surfaces 130b is used, the first hook 216b and the second hook 216c are engaged with the other of the first surface 130a and the second surface 130b of the accommodation portion 130. In other words, when the blocking structure 216a and the accommodating portion 130 abut against one surface of the accommodating portion 130, the first hook 216b and a second hook 216c can be engaged with the periphery of the other surface of the accommodating portion 130. Thereby, the joint processing cassette 200 is firmly clamped in the accommodating portion 130 of the tool body 100. Referring again to FIGS. 7A and 7B, in order to allow both right-handed and left-handed operators to operate the clamp tool 10 of the present invention, the joint processing cassette 200 of the present invention can be assembled into the first surface 130a of the accommodating portion 130. The tool body 100 can also be assembled into the tool body 100 from the second surface 130 b of the accommodating portion 130. In detail, since the second jaw handle 120 of the present invention is pivotally connected to the first jaw handle 110 and rotates relative to the first jaw handle 110, the first jaw handle 110 can be defined as a fixed jaw handle, and the second The clamp handle 120 is defined as a movable clamp handle. Therefore, when a right-handed operator is operating the clamp tool 10, the joint processing cassette 200 can be assembled into the tool body 100 from the second surface 130b of the accommodating portion 130 (as shown in FIG. 7A). In this way, a right-handed worker can hold the cable connector to be processed with the left hand and the clamp tool 10 with the right hand, in which the first pliers handle 110 is held against the thumb and palm of the right hand, and the right thumb is applied. The outer four fingers hold the second pliers handle 120 to facilitate the application of force to the second pliers handle 120 to further process the cable connector. Similarly, when a left-handed operator is operating the clamp tool 10, the joint processing cartridge 200 can be assembled into the tool body 100 from the first surface 130a of the accommodating portion 130 (as shown in FIG. 7B). In this way, the left-handed operator can hold the cable connector to be processed with the right hand and the clamp tool 10 with the left hand, in which the first pliers handle 110 is held against the palm of the left hand and the thumb, and the left thumb is applied The outer four fingers hold the second pliers handle 120 to facilitate the application of force to the second pliers handle 120 to further process the cable connector. To achieve the above purpose, the first hooks 216b and the second hooks 216c of the second holding portion 216 are asymmetrically disposed on both sides of the body 210 along the first axis L1. In addition, the first holding portion 132 of the accommodating portion 130 includes a first card slot 132a, a second card slot 132b, a third card slot 132c, and a fourth card slot 132d. Among them, the first card slot 132a and the third card slot 132c are disposed on an inner side of the accommodating portion 130 with respect to the first axis L1, and the second card slot 132b and the fourth card slot 132d are disposed opposite the accommodating portion 130. Opposite the first axis L1 is the other inner side. The first card slot 132a and the fourth card slot 132d are, for example, located at the same height of the accommodating portion 130, and the second card slot 132b and the third card slot 132c are located at the same height of the accommodating portion 130. In addition, the first card slot 132a and the second card slot 132b are recessed to a depth in the direction of the second axis L2, and the third card slot 132c and the fourth card slot 132d are recessed to a depth in the direction of the second axis L2. The surface of the first surface 130a of the self-accommodating portion 130 is recessed to a depth in the direction of the second axis L2. With the above structure, when the main body 210 of the joint processing cassette 200 is assembled into the accommodation portion 130 from the second surface 130b in the direction of the second axis L2 (as shown in FIG. 7A), the first hook 216b and the second card The hooks 216c are respectively latched in the first and second latching slots 132a and 132b, and finally snap against the first surface 130a of the receiving portion 130, while the blocking structure 216a abuts against the second of the receiving portion 130. Surface 130b. Similarly, when the main body 210 of the joint processing cassette 200 is assembled into the receiving portion 130 from the first surface 130a along the direction of the second axis L2 (as shown in FIG. 7B), the first hook 216b and the second hook 216c They are respectively snapped into the fourth card slot 132d and the third card slot 132c, and finally snap against the second surface 130b of the accommodating portion 130, while the blocking structure 216a abuts against the second surface 130b of the accommodating portion 130. on. In this way, the joint processing cassette 200 can be easily snapped into the accommodating portion 130 by the first surface 130a or the second surface 130b of the accommodating portion 130 of the tool body 100 as required, so whether it is left-handed or The right-handed operators can hold the clamp tool 10 of the present invention according to their dominant hands to perform the cable joint processing operation. In summary, in the clamp tool of the present invention, the joint processing cassette is detachably arranged on the tool body, so when an operator wants to process different types of cable joints, he can selectively assemble appropriate joints. The processing cassette is processed on the tool body for processing operations, which can be applied to the processing of cable connectors of various specifications without the need to prepare specific clamp tools for each type of cable connector, which reduces the operator's work And the trouble of carrying, also reduces the cost of purchasing tools. In addition, the clamp tool of the present invention can simultaneously perform crimping and cutting operations on cable joints. Therefore, the clamp tool of the present invention can securely combine the connector body and the outer layer of the cable in only one operation stroke, electrically connect the electrode sheet of the connector body and the core wire in the cable for transmitting signals, and simultaneously remove excess Cable. In addition, the cooperation between the first holding portion and the second holding portion of the present invention not only allows the joint processing cassette to be stably arranged in the receiving portion of the tool body, but also has the advantage of facilitating disassembly and assembly by the operator. Meet the needs of operators in use and operation. Furthermore, the clamp tool of the present invention takes into account the operation modes of right-handed and left-handed operators, so that both the left-handed and right-handed operators can conveniently hold the present invention according to their dominant hands. Clamp tool for cable joint processing operations. The above-mentioned embodiments are only for explaining the technical ideas and characteristics of the present invention. The purpose is to enable those skilled in the art to understand the content of this creation and implement it accordingly. It should not be used to limit the patent scope of the present invention. In other words, equivalent changes or modifications made in accordance with the spirit disclosed by the present invention should still be covered by the patent scope of the present invention.

10‧‧‧ Clamp Tool
100‧‧‧tool body
110‧‧‧First pliers handle
120‧‧‧Second pliers handle
130‧‧‧accommodation department
131‧‧‧ accommodation opening
130a‧‧‧First side
130b‧‧‧Second Side
132‧‧‧First Holding Department
132a‧‧‧First card slot
132b‧‧‧Second Card Slot
132c‧‧‧Third Card Slot
132d‧‧‧Fourth card slot
140‧‧‧Driver
200‧‧‧Joint processing cassette
210‧‧‧ Ontology
212‧‧‧Sliding groove
214‧‧‧Processing opening
216‧‧‧Second Holding Department
216a‧‧‧stop structure
216b‧‧‧The first card hook
216c‧‧‧Second Card Hook
220‧‧‧Processing block
222‧‧‧Connection Department
224‧‧‧Processing structure
224a‧‧‧First processing structure
224b‧‧‧Second Processing Structure
50‧‧‧ crystal head
52‧‧‧Pressed structure
54‧‧‧electrode pads
56‧‧‧ protrusion
60‧‧‧cable
62‧‧‧core
L1‧‧‧first axis
L2‧‧‧Second axis
P1‧‧‧Block structure
P2‧‧‧Press block structure

FIG. 1A is a schematic diagram of a clamp tool in an idle state according to an embodiment of the present invention. FIG. 1B is a schematic diagram of a clamp tool in a processing state. 2A and 2B are schematic diagrams showing the structure of a processing block of a joint processing cassette in an idle position. 3A and 3B are schematic diagrams showing the structure of the processing block of the joint processing cassette on the other side of the idle position. 4A and 4B are schematic diagrams showing the processing blocks of the joint processing cassette of FIG. 2A and FIG. 2B at the processing positions. 5A and 5B are schematic diagrams showing the processing blocks of the joint processing cassette of FIG. 3A and FIG. 3B at the processing positions. FIG. 6A illustrates a combination diagram of a crystal connector and a cable before crimping according to an embodiment of the present invention. FIG. 6B is a schematic diagram of a crimping process between a crystal connector and a cable according to an embodiment of the present invention. FIG. 7A is a schematic diagram of the combination of the accommodating part of the tool body and the joint processing cassette on one side of the present invention. FIG. 7B is a schematic diagram of the combination of the accommodating portion of the tool body of the present invention with the joint processing cassette on the other side.

Claims (25)

A method of assembling a reassembled clamp tool, the method includes: (a) selecting a removable cassette corresponding to a selected joint type, the removable cassette being a crimpable cable A single cassette for driving the electrode pads and the core wire of the cutting cable; and (b) inserting the removable cassette into a tool body. The method of claim 1, further comprising removing a first removable cassette from the tool body before inserting the selected removable cassette into the tool body. The method of claim 2, wherein selecting a removable cassette includes selecting a cassette having a processing structure different from the first removable cassette. The method of claim 1, wherein inserting the cassette further comprises engaging a cassette holding portion to a tool body holding portion to removably fix the cassette in the tool body. The method of claim 4, wherein inserting the cassette further comprises aligning the cassette in the tool body. The method of claim 4, wherein inserting the cassette further comprises inserting the cassette until a stop structure of the cassette holding portion abuts a first surface of the tool body. The method of claim 6, wherein inserting the cassette further comprises inserting the cassette until a hook of one of the cassette holding portions abuts against a second surface of the tool body spaced from a first surface of the tool body on. The method of claim 1, wherein inserting the cassette includes aligning a slidable block of the cassette with a slidable driving portion of the tool body. The method of claim 1, wherein inserting the cassette includes releasably engaging a slidable drive portion of the tool body with a slidable block of the cassette. The method of claim 9, wherein the slidable block of the cassette is removably engaged with the slidable driving part of the tool body, including engaging so that the slide block of the cassette is slidable with the tool body The linear movement of the drive unit responds. The method of claim 9, wherein the slidable block of the cassette is removably engaged with the slidable driving part of the tool body, including engaging a male structure and a female structure so that when the cassette is located in the tool body At this time, the driving part is held to prevent it from detaching from the sliding block along a driving axis. The method of claim 9, wherein the slidable block of the cassette removably engages the slidable driving portion of the tool body, and includes inserting a geometric protrusion into a corresponding card slot matching the geometric protrusion . The method of claim 1, wherein inserting the cassette includes releasably engaging a slidable block of the cassette with a slidable driving portion of the tool body, the slidable block of the cassette and the tool body. The slidable driving part is slidable along a driving shaft, and inserting the cassette includes inserting the cassette along an axis transverse to the driving shaft. A method for assembling a reassembled jaw tool, the method comprising: (a) removing and fixing the tool from a tool body without removing a fixing member from the reassemble jaw tool; A first cassette in the body; (b) selecting a second cassette; and (c) inserting the second cassette into the tool body after removing the first cassette; and (d) The second cassette is fixed to the tool body using a removable fixing member. The method of claim 14, wherein removing the first cassette includes removing a first cassette corresponding to a first connector type, and wherein inserting the second cassette into the tool body includes inserting corresponding to a first One of the two connector types is the second cassette. The method of claim 14, further comprising selecting the first cassette having a first-size connector opening, and wherein selecting the second cassette includes selecting the second cassette having a connector opening different from the first cassette. Cassette. The method of claim 14, wherein inserting the second cassette further comprises engaging a second cassette holding portion to a tool body holding portion to removably fix the second cassette in the tool body. The method of claim 14, wherein inserting the second cassette includes combining a slidable block of the second cassette with a slidable driving portion of the tool body. The method of claim 17, wherein inserting the second cassette further comprises inserting the second cassette until a stop structure of the second cassette holding portion abuts against a first surface of the tool body. The method of claim 19, wherein inserting the second cassette further includes inserting the second cassette until a hook of the second cassette holding portion abuts against the tool spaced from a first surface of the tool body One of the bodies is on the second surface. The method of claim 14, wherein inserting the second cassette includes detachably engaging a slidable block of the second cassette with a slidable driving portion of the tool body. The method of claim 21, wherein the slidable block of the second cassette releasably engages the slidable driving portion of the tool body, including engaging the sliding block of the second cassette to the tool body The slidable linear movement of the drive unit responds. The method of claim 14, wherein inserting the second cassette includes releasably engaging a slidable block of the second cassette with a slidable driving portion of the tool body, and the slidable of the second cassette The block and the slidable driving part of the tool body are slidable along a driving shaft, and inserting the second cassette includes inserting the second cassette along an axis transverse to the driving shaft. A method of assembling a reassembled clamp tool, the method includes: (a) selecting a removable cassette corresponding to a selected joint type; (b) inserting the removable cassette into a tool body (C) where inserting the cassette includes detachably engaging a slidable sliding block of the cassette to a slidable driving portion of the tool body; and (d) wherein the cassette is removably A slidable machining block is engaged with a slidable drive portion of the tool body, and includes a male structure and a female structure that are engaged so that when the cassette is located in the tool body, the drive portion is held to prevent it from driving along The axis is detached from the slider. A method of assembling a reassembled clamp tool, the method includes: (a) selecting a removable cassette corresponding to a selected joint type; (b) inserting the removable cassette into a tool body (C) where inserting the cassette includes detachably engaging a slidable sliding block of the cassette to a slidable driving portion of the tool body; and (d) wherein the cassette is removably A slidable machining block is engaged with a slidable driving part of the tool body, and includes inserting a geometric protrusion into a corresponding storage groove corresponding to the geometric protrusion.