阅读说明：本技术 拉杆组件联结件 (Tie rod assembly connector ) 是由 特雷弗·G·赛伯特 于 2019-09-18 设计创作，主要内容包括：本申请公开了一种拉杆组件联结件,包括套管(22)和延伸到该套管中的拉杆轴(24),使得该拉杆轴和该套管彼此重叠。在该重叠区域中,该拉杆轴和该套管中的每一者具有至少一组开口(32,34)。C形夹具(36)围绕该套管设置。该夹具具有接合两个套管半部的弯曲内表面。该夹具具有与该弯曲内表面向外间隔开的第一组孔和延伸到该弯曲内表面的第二组孔。第一紧固件(42)延伸穿过该第一组孔以将该夹具绷紧到该套管上。第二紧固件(44)延伸穿过该第二组孔并穿过该拉杆轴和该套管中的所对准的开口。(A tie rod assembly coupling includes a sleeve (22) and a tie rod shaft (24) extending into the sleeve such that the tie rod shaft and the sleeve overlap one another. In the overlap region, each of the tie rod axle and the sleeve has at least one set of openings (32, 34). A C-shaped clamp (36) is disposed about the sleeve. The clamp has a curved inner surface that engages the two casing halves. The clamp has a first set of apertures spaced outwardly from the curved inner surface and a second set of apertures extending to the curved inner surface. A first fastener (42) extends through the first set of apertures to tighten the clamp onto the sleeve. A second fastener (44) extends through the second set of bores and through aligned openings in the tie rod axle and the sleeve.)

1. A tie rod assembly coupler, comprising:

a sleeve extending from an open first end along an axis, the sleeve having at least one slot extending in an axial direction from the open first end and dividing an end of the sleeve into two sleeve halves on opposite sides of the at least one slot;

a pull rod end comprising a pull rod arbor extending into the open first end of the sleeve such that the pull rod arbor and the tube end of the sleeve overlap one another along an overlap region;

in the overlap region, the pull rod axle has at least one set of openings and the sleeve has at least one set of openings;

a generally C-shaped clamp disposed around the casing in the overlap region, the clamp having a curved inner surface engaging the two casing halves, the clamp having a first set of apertures spaced outwardly from the curved inner surface and having a second set of apertures extending to the curved inner surface;

a first fastener extending through the first set of holes of the clamp and tightening the curved inner surface of the clamp onto the sleeve to establish a secure connection between the sleeve and the tie rod axle; and

a second fastener extending through the second set of holes of the clamp and through a set of openings of the tie rod axle and through a set of openings of the bushing.

2. The tie rod coupling of claim 1, wherein the tie rod shaft is unthreaded.

3. The tie rod link of claim 1, wherein said clip is made as a single piece.

4. The tie rod link of claim 3, wherein said clip has a pair of fingers extending away from said curved inner surface, and wherein said fingers are spaced apart from one another, and wherein said first set of apertures are located in said fingers.

5. The tie rod link of claim 4, wherein the at least one slot of the sleeve is aligned with a gap between the spaced fingers such that tightening the first fastener onto the clip partially closes the at least one slot of the sleeve.

6. The tie rod coupling of claim 4, wherein a diameter of the first fastener is greater than a diameter of the openings in the bushing and the tie rod shaft.

7. The tie rod coupling of claim 1, wherein the tie rod shaft and the bushing and the clamp are all made of metal.

8. The tie rod coupling of claim 1, wherein said first fastener and said second fastener are bolts.

9. The tie rod coupling of claim 1, wherein the first fastener and the second fastener are the only fasteners connecting the tie rod shaft with the bushing.

10. A method of manufacturing a drawbar link, the method comprising the steps of:

preparing a sleeve extending along an axis from an open first end, the sleeve having at least one slot extending in an axial direction from the open first end and the at least one slot dividing the end of the sleeve into two sleeve halves on opposite sides of the at least one slot;

inserting a pull rod axle of a pull rod end into the open first end of the sleeve such that the pull rod axle and the sleeve overlap one another along an overlap region;

aligning a set of openings in the pull rod axle with a set of openings in the sleeve;

inserting a generally C-shaped clamp around the casing in the overlap region, the C-shaped clamp having a curved inner surface engaging the two casing halves, and the clamp having a first set of apertures spaced outwardly from the curved inner surface and having a second set of apertures extending to the curved inner surface;

inserting a second fastener through the second set of holes of the clamp and through the aligned openings of the drawbar shaft and the bushing; and

inserting a first fastener through the first set of holes of the clamp and tightening the curved inner surface against the sleeve with the first fastener to establish a secure connection between the sleeve and the tie rod shaft.

11. The method of claim 10, wherein the tie rod shaft is unthreaded.

12. The method of claim 11, wherein the clamp is made as a single piece.

13. The method of claim 10, wherein the C-clamp includes a pair of fingers extending away from the curved inner surface and spaced apart from each other by a gap, and further comprising the step of aligning the gap with the at least one slot of the sleeve.

14. The method of claim 10, wherein the diameter of the first fastener is greater than the diameter of the opening in the bushing and the tie rod axle.

15. The method of claim 10, wherein the tie rod shaft and the sleeve and the clamp are all made of metal.

1. Field of the invention

The present application relates generally to a tie rod coupler assembly of the type that may be used in an agricultural combine. The present application is also applicable to other tie rod assemblies that require length adjustment without the use of threaded couplings.

2. Related Art

Fig. 1 illustrates a known type of tie rod coupler assembly configured for use with an agricultural combine harvester. The assembly includes a sleeve and an unthreaded pull rod shaft inserted into the sleeve. The bushing and the tie rod axle are each provided with spaced apart sets of aligned bolt openings for receiving bolts to fixedly attach the components together, thereby fixing the length of the tie rod coupler assembly. The assembly also includes a plurality of bolt bases fabricated as separate components from each other, from the sleeve, and from the tie rod axle.

In this known tie rod coupler assembly, the tie rod axle is fixedly attached to the bushing by first aligning the bolt holes with each other so that the assembly has a desired length, and then manually placing the bolt bases on the bushing. Next, a plurality of bolts are inserted through the bolt bases, through the bushings, and through the tie rod shafts, and the lock nuts are tightened onto the bolts.

Background

Summary of the invention and advantages

One aspect of the present application relates to a tie rod assembly coupling that includes a bushing and a tie rod end. The sleeve extends from the open first end along an axis and has at least one slot extending in an axial direction from the open first end. The at least one slot divides a portion of the cannula into two cannula halves on opposite sides of the at least one slot. The pull rod end includes a pull rod arbor that extends into the open first end of the sleeve such that the pull rod arbor and the sleeve overlap one another along an overlap region. In the overlap region, each of the pull rod axle and the sleeve has at least one set of openings. A generally C-shaped clamp is disposed around the sleeve in the overlap region. The clamp has a curved inner surface that engages the two casing halves. The clamp has a first set of apertures spaced outwardly from the curved inner surface and has a second set of apertures extending to the curved inner surface. A first fastener extends through the first set of holes of the clamp to tighten the curved inner surface of the clamp onto the sleeve to establish a secure connection between the sleeve and the tie rod axle. The second fastener extends through the second set of holes of the clamp and through a set of openings of the tie rod axle and through a set of openings of the bushing.

It has been found that tie rod assembly couplings provide a more robust and durable connection between the tie rod axle and the bushing, with little or no additional cost, and can be installed more quickly than other known couplings.

According to another aspect of the application, the tie rod shaft is unthreaded.

According to another aspect of the present application, the clamp is made as a single piece.

According to another aspect of the application, the clip has a pair of fingers extending away from the curved inner surface and spaced apart from each other, and wherein the first set of holes are located in the fingers.

According to another aspect of the application, the at least one slot of the sleeve is aligned with the gap between the spaced apart fingers such that tightening the first fastener onto the clip partially closes the at least one slot of the sleeve.

According to yet another aspect of the present application, the first fastener has a diameter that is greater than a diameter of the opening in the sleeve and the tie rod shaft.

According to yet another aspect of the present application, the pull rod axle, the sleeve, and the clamp are all made of metal.

According to another aspect of the application, the first and second fasteners are bolts.

According to yet another aspect of the present application, the first fastener and the second fastener are the only fasteners connecting the tie rod shaft with the bushing.

Another aspect of the present application relates to a method of manufacturing a pull rod coupling. The method includes the step of preparing a cannula extending from an open first end along an axis. The sleeve has at least one slot extending in an axial direction from the open first end and dividing the sleeve into two sleeve halves on opposite sides of the at least one slot. The method continues with the steps of: the pull rod axle of the pull rod end is inserted into the open first end of the sleeve such that the pull rod axle and the sleeve overlap one another along an overlap region. The method continues with the steps of: a set of openings in the tie rod shaft is aligned with a set of openings in the sleeve. The method continues with the steps of: a generally C-shaped clamp is inserted around the cannula in the overlap region. The C-clamp has a curved inner surface engaging the two ferrule halves, has a first set of holes spaced outwardly from the curved inner surface, and has a second set of holes extending to the curved inner surface. The method continues with the steps of: a first fastener is inserted through the first set of holes of the clamp and the curved inner surface is tightened against the sleeve with the first fastener to establish a secure connection between the sleeve and the tie rod shaft. The method continues with the steps of: a second fastener is inserted through the second set of holes of the clamp and through the aligned openings of the tie rod axle and the sleeve.

According to another aspect of the application, the tie rod shaft is unthreaded.

According to another aspect of the present application, the clamp is made as a single piece.

According to another aspect of the application, the C-clamp includes a pair of fingers extending away from the curved inner surface and spaced apart from each other by a gap, and wherein the method further includes the step of aligning the gap with the at least one slot of the ferrule.

According to another aspect of the application, the diameter of the first fastener is greater than the diameter of the opening in the sleeve and the drawbar shaft.

According to yet another aspect of the present application, the pull rod axle and the sleeve and the clamp are made of metal.

Drawings

These and other features and advantages of the present application will become more readily appreciated when considered in connection with the following description of the presently preferred embodiments, the appended claims, and the accompanying drawings in which:

FIG. 1 is a perspective and front view of a tie rod assembly coupler of a known type;

FIG. 2 is a perspective and elevation view of a pull rod coupler assembly constructed in accordance with one aspect of the present application;

FIG. 3 is an enlarged view of a portion of the drawbar link assembly of FIG. 2; and is

FIG. 4 is an exploded view of the tension rod coupler assembly of FIG. 2.

Detailed Description

Referring to the drawings, wherein like numerals indicate corresponding parts throughout the several views, an exemplary embodiment of a tie rod assembly 20 constructed in accordance with one aspect of the present application is generally shown in fig. 2-4. The tie rod assembly 20 of the exemplary embodiment is specifically configured for use with an agricultural combine. However, it should be understood that the pull rod coupler assembly may alternatively be configured for use with other types of vehicles.

The tie rod assembly 20 includes a sleeve 22 and a tie rod end. The sleeve 22 is generally cylindrical in shape and extends along an axis from a first end of the opening to a second end of the opening. The tie rod end includes a nipple 24 and a tie rod axle 26 that is cylindrical and extends away from the nipple 24. The pull rod axle 24 is shaped and dimensioned for insertion into the first open end of the sleeve 22 such that, in an assembled state, the pull rod axle 24 is partially received in the open first end of the sleeve 22. Thus, in the assembled state, the sleeve 22 and the tie rod shaft 24 overlap each other along an overlapping region. In the overlap region, the sleeve 22 and the pull rod axle 26 are provided with cooperating length adjustment features that allow the length of the pull rod axle 26 extending out of the sleeve 22 to be selected prior to fixedly attaching these components together. In other words, the length of the drawbar assembly 20 is adjustable. In contrast to other known tie rod assemblies, in the exemplary embodiment, the tie rod axle 26 is unthreaded, and thus the length adjustment feature is essentially unthreaded.

The sleeve 22 has a slot 28 that begins at the first end of the opening and extends axially toward the second end of the opening. The slot 28 divides the end of the sleeve 22 into two sleeve halves 30a, 30b on opposite sides of the slot 28. In an exemplary embodiment, each end of the sleeve 22 has only a single slot 28. However, it should be understood that two or more slots may be provided.

The tie rod shaft 26 includes a plurality of bolt openings 32 arranged in a plurality of groups axially spaced from one another. The bolt openings 32 in each set are aligned with and diametrically opposed to each other. The sleeve 22 has a corresponding single set of bolt openings 34 that can be aligned with any of the set of bolt openings 32 on the tie rod axle 26 by: the pull rod shaft 26 is slid further into or out of the sleeve 22 until alignment is achieved. The length of the tie rod assembly 20 can be selected by selecting which set of bolt openings 32 in the tie rod axle 26 are aligned with which set of bolt openings 34 in the sleeve 22. The single set of bolt openings 32 of the sleeve 22 of the exemplary embodiment differs from other known sleeves that typically include multiple sets of bolt openings. Thus, the sleeve 22 of the exemplary embodiment may be manufactured faster and more cost effectively than other known sleeves, as fewer bolt openings 34 must be formed into the sleeve 22.

In the overlap region, the C-clamp 36 is partially wrapped over the sleeve 22 for fixedly attaching the sleeve 22 and the tie rod shaft 26 in a very durable and secure manner. The clamp 36 has a curved inner surface that contacts the outer surface of both casing halves 30a, 30 b. The clip 36 has a pair of fingers 38 with a pair of fingers 38 extending away from the curved inner surface and spaced apart from each other by a gap. The clip 36 is oriented such that the gaps between the fingers 38 are aligned with the slots 28 in the sleeve 22. The fingers 38 have inner surfaces that diverge from one another in a direction away from the sleeve 22 to allow the clip 36 to be more easily inserted onto the sleeve 22. The fingers 38 also have a planar outer surface to present a bolt base 40 to provide a flat surface for a pair of fasteners 42, 44 discussed in further detail below. The appearance of the bolt base 40 may vary based on the needs in the manufacturing process or application.

The fingers 38 present a first set of holes that are coaxially aligned with each other and receive a first fastener 42. The first set of holes are spaced from the curved inner surface of the clamp 36 and therefore the first fastener 42 does not extend through the sleeve 22 or the tie rod shaft 26. In an exemplary embodiment, the first fastener 42 has the form of a bolt and nut. Tightening the first fastener 42 (screwing the nut further onto the bolt) has the effect of partially closing the gap between the fingers 38, which in turn tightens the curved inner surface against the overlapping region of the sleeve 22. Tightening the clamp 36 on the sleeve 22 partially closes the slot 28 of the sleeve 22 so that the sleeve 22 and the tie rod shaft 26 tightly engage to establish a secure and durable connection between the sleeve 22 and the tie rod shaft 26. It has been found that this configuration provides superior clamping force from the sleeve 22 onto the tie rod shaft 26 compared to other known tie rod assemblies.

The fixture 36 also has a second set of holes that are coaxially aligned with each other and extend to the curved inner surface. The second fastener 44 extends through both of the second holes in the clamp and through the aligned bolt openings 32,34 in the tie rod axle 26 and the bushing 22, respectively. The second fastener 44 serves as a backup retention device in the event of failure of the primary retention device (first fastener 42). Thus, in the exemplary embodiment, the sleeve 22 is secured with the pull rod axle 26 by only two fasteners 42, 44. In addition to providing a backup retention device, the second fastener 44 also provides alignment between the bushing 22 and the tie rod axle 26, and ultimately establishes the desired length of the tie rod assembly 22.

In an exemplary embodiment, when the bolts and nuts of the first and second fasteners 42, 44 are installed in the tie rod assembly 20, the heads of these bolts and nuts are in direct contact with the planar bolt base 40 formed on the clamp 36.

The sleeve 22, tie rod shaft 26, and clamp 36 are all preferably made of a metal, such as steel, alloy steel, aluminum, or aluminum alloy, and may be formed by any one or more suitable processes. For example, the clamp 36 is preferably cast into its final form as a single monolithic piece. The bolt openings 32,34 are preferably formed into the tie rod axle 26 and the bushing 22, respectively, by a stamping or machining operation.

In an exemplary embodiment, the diameter of the first fastener 42 is greater than the diameter of the second fastener 44 and greater than the diameter of the bolt openings 32, 34. Thus, bolts that can be tightened to higher installation torques can be used as the first fasteners 42, thereby increasing the potential clamping force provided by the clamp 36 on the sleeve 22 and the tie rod shaft 26.

In some applications, the tie rod assembly may be provided with multiple clamps or with a single clamp utilizing more than two fasteners.

In use, the clamp 36 provides a very secure connection between the sleeve 22 and the tie rod axle 26 by compressing the sleeve 22 against the outer surface of the tie rod axle 26, despite the inclusion of only two fasteners 42, 44. This is in contrast to other known connection devices that require three or more fasteners. In addition, the tie rod assembly 20 does not require any separate piece bolt seat formed on other known connection devices and that must be manually placed onto the bushing before being fixedly attached to the tie rod axle. Thus, the process for connecting the sleeve 22 of the example tie rod assembly 20 with the tie rod axle 26 can be accomplished faster, less expensively, and with fewer parts than those of other known connection devices.

Another aspect of the present application relates to a method for manufacturing a tie rod assembly 20, such as the tie rod assembly 20 shown in fig. 2-4 and discussed above. The method comprises the following steps: the sleeve 22 is prepared and one end of the pull rod shaft 26 is inserted into the open first end of the sleeve 22. The method continues with the steps of: a set of bolt openings 32 in the tie rod shaft are aligned with a set of bolt openings 34 in the sleeve 22. The method continues with the steps of: the clamp 36 is inserted around the casing 22 in the overlap region and direct contact is established between the curved inner surface of the clamp 26 and the outer surface of the casing 22. The method continues with the steps of: the first fastener 42 is inserted through the first set of holes in the clamp 36 and the curved inner surface of the clamp 36 is tightened onto the sleeve 22 to establish a secure connection between the sleeve 22 and the tie rod shaft 26. The method continues with the steps of: the second fastener 44 is inserted through the second set of holes in the clamp 36 and through the aligned bolt openings 32,34 of the tie rod axle 26 and the bushing 22, respectively. Preferably, the step of inserting the second fastener 44 through the second set of holes in the clamp 36 and through the aligned bolt openings 32,34 of the tie rod axle 26 occurs prior to inserting the first fastener 42 through the first set of holes of the clamp 36 to provide alignment between the bushing 22 and the tie rod axle 26 and to establish the desired length of the tie rod assembly 20 prior to tightening the clamp 36 down onto the bushing 22.

Obviously, many modifications and variations of the present application are possible in light of the above teachings, and may be practiced otherwise than as specifically described within the scope of the appended claims. In addition, it should be understood that all features of all claims and all embodiments may be combined with each other as long as they are not contradictory to each other.