阅读说明：本技术 电动锁定系统移土设备及方法 (Electric locking system earth moving equipment and method ) 是由 C·哈德 P·韦伯 于 2018-03-07 设计创作，主要内容包括：一种电动锁定装置,用于将例如齿或适配器固定到地面接合系统,锁具有内部电机、通过远程无线技术操作来解锁和锁定该锁定装置的传感系统,以及用于电动锁定装置的锁定和解锁的无线发送手持装置,其中电机以及驱动和电子响应电路都被包含在该电动锁定装置内。(A powered locking device for securing, for example, a tooth or an adapter to a ground engaging system, the lock having an internal motor, a sensing system operated by remote wireless technology to unlock and lock the locking device, and a wireless transmitting handset for locking and unlocking the powered locking device, wherein the motor and drive and electronic response circuitry are contained within the powered locking device.)

1. A shovel for an earth moving apparatus having a shovel edge and a plurality of ground engaging bits removably attached to the shovel edge, characterized by:

a plurality of bit bases on the blade;

a plurality of tool bits releasably carried on respective said tool bit seats, said tool bits each defining a hollow interior cavity adapted to a respective said tool bit seat;

a lock receiving recess in each of said tool tip seats;

a power bit lock received in the respective lock receiving recess, the power bit lock including a movable lock member and a power drive operable to drive the lock member between two positions;

a lock receiving receptacle accessible within the hollow interior of each said bit and oriented to a position corresponding to the respective lock receiving recess; and the number of the first and second groups,

a remote control device capable of sending a signal to the respective electric drive device.

2. The shovel for an earth moving apparatus of claim 1 further characterized by a drive gear rack attached to each of the movable lock members, a drive gear connected with the gear rack, a motor coupled to the drive gear, the motor located within the electric bit lock.

3. The shovel for an earth moving apparatus of claim 2 further characterized in that the motorized bit lock is fully contained within the bit mount, wherein the movable lock member is movable by remote operation of the motor and the drive gear to move the lock member in and out of engagement in the lock receptacle in the bit.

4. The shovel for an earth moving apparatus of claim 3, further characterized in that the blade mount is fixedly secured to the shovel.

5. The shovel for an earth moving apparatus of claim 3, further characterized by a plurality of tooth adapters removably attached to respective ones of the bit mounts.

6. The shovel for an earth moving apparatus of claim 3, further characterized in that respective teeth are mounted on respective head bases on the shovel.

7. The shovel for an earth moving apparatus of claim 3, further characterized by a plurality of lock recesses formed in respective ones of the bit mounts, the plurality of lock recesses formed in a side portion of the bit mounts and along an axis perpendicular to a longitudinal axis of each of the bit mounts, and wherein the lock receiving socket is formed in an interior of each of the bit mounts, aligned along an axis perpendicular to a longitudinal axis of each of the bit mounts, and positioned to align with the respective lock recesses in the bit mounts when the bit is slid over the bit mounts.

8. A remotely operated power tool lock for securing a tool bit to a tool bit holder on a ground engaging system, the tool lock being completely concealed within the tool bit holder and the tool bit, the tool lock comprising:

a lock housing body adapted to be placed in one of the bit and the bit mount of the ground engaging system;

a lock member slidably secured in the lock housing body;

a drive transmission connected to the lock member operable to extend and retract the lock member relative to the lock housing body;

a wireless response motor operable to control the drive transmission means; and the number of the first and second groups,

a remote wireless controller operable to send a specific coded signal to each respective said tool lock and to operate its respective said wireless response motor.

9. The power tool lock of claim 8, further characterized in that the bit mount defines a bit support and a lock-receiving recess, and wherein the bit defines a hollow interior adapted to the bit support and a lock-receiving bay accessible in the hollow interior of the bit for receiving the lock member from the lock housing body.

10. The power tool lock of claim 9 further characterized in that the lock member is attached to a gear bar and includes a drive gear engaged with the gear bar, the drive gear being responsive to operation of the motor to extend and retract the lock member relative to the lock housing body.

11. The power tool lock of claim 10, further characterized in that the tool bit mount is fixedly secured to the ground engaging system.

12. The power tool lock of claim 11, further characterized by a bit adapter removably attached to the respective bit mount.

13. The power tool lock of claim 12, further characterized in that a respective tool bit is mounted on a respective tool bit mount.

14. The power tool lock of claim 12, further characterized in that a respective bit is mounted on a respective bit adapter.

15. The power tool lock of claim 13, comprising a lock recess formed in a side portion of each said tool tip carrier and along an axis perpendicular to a longitudinal axis of each said tool tip carrier, wherein said lock receiving pocket is formed in an interior of each said tool tip, aligned along an axis perpendicular to a longitudinal axis of said tool tip, and positioned to align with a corresponding said lock recess in said tool tip carrier when said tool tip is slid thereon.

16. A method of remotely securing a bit to a bit holder on a ground-engaging shovel, comprising:

forming the bit holder with an internal lock receiving recess;

a bit defining a hollow interior with a locking receptacle;

placing a tool lock in the recess of the tool bit carrier, the tool lock having a lock member slidably secured in a lock housing body and operable in response to an internally positioned motor to move the lock member, and

remotely controlling the motor by a remote wireless controller operable to send a specific coded signal to the tool lock to operate the motor.

17. The method of remotely securing a tool bit to a tool bit holder of claim 16, further characterized by placing the tool bit lock in the recess of the tool bit holder, placing a tool bit defining a hollow interior above the tool bit holder and the tool lock, the tool bit defining a hollow interior having a lock receptacle,

aligning the lock receptacle with the tool lock housing recess in the tool bit holder, an

Operating said wireless response motor via a remote wireless controller external to said tool tip carrier and said tool tip.

Technical Field

The present invention relates to earth moving equipment and machinery, and in particular to the retention of teeth on such earth moving machinery, for example. In particular, the present invention relates to a novel motorized locking system having such teeth, which is operated by remote wireless for moving a separate locking mechanism between locked and unlocked positions. The locking system according to the invention is completely hidden within the components of the earth moving machine, such as the toothholder and the teeth themselves, so that the locking system is not exposed to the environment in which the machine is used.

Background

Many machines, particularly earth moving machines, include ground engaging tools for performing tasks such as digging, tilling, turning, loading and/or digging. Such ground engaging tools typically include a shovel having one or more blades with edges. If such blades are not protected, contact with soil, rock, and other materials may damage or abrade the edges of the blade. Repairing or replacing the blade portion of such ground engaging tools due to wear or damage to the edge can involve significant expense. Accordingly, many ground engaging tools include ground engaging members such as teeth, adapters, and shrouds that are mounted on the blade to protect the edge of the blade from contact with soil, rock, and other materials.

In most cases, the teeth and adapters are secured to the shovel by some form of wedge arrangement. In many cases, such wedges are manually held in place, typically by only hammering. In other cases, various lock or wedge systems have been developed in which the wedging is achieved by some form of screw mechanism. The screw mechanism is in turn operated by hand or a wrench.

It will be appreciated that even the more complex screw mechanisms for locking the tooth to the adapter must still be accessible from the exterior of the tooth or the adapter or both. This is considered a possible cause of the problem due to the harsh environment of alternately moving the shovel into the soil or debris and then removing it again. The teeth and mechanism are subject to extreme wear and forces that operate first to push the teeth toward the adapter, then to push the teeth away from the adapter, and so on.

When the teeth must be replaced, the shovel must be cleaned to facilitate removal of the mechanism. If the locking mechanism is damaged by use, then removal of such locking mechanism becomes a problem.

The present invention overcomes the problem of hiding the entire locking mechanism within the adapter and body of the tooth and allows the locking mechanism to respond independently to wireless technology from outside the tooth and adapter.

Disclosure of Invention

The present invention provides a shovel for a soil moving apparatus, the shovel having a shovel edge and a plurality of ground engaging bits removably connected to the shovel edge, the shovel comprising: a bit mount mounted on the blade, a bit releasably carried on the bit mount; a lock receiving recess within the tool bit holder; an electric bit lock received in the lock receiving recess in the bit mount, the electric bit lock including a movable lock member, and an electric drive arrangement operable to drive the lock member between two positions, a lock receiving socket located in the interior of the bit and oriented to align with the lock receiving recess in the bit mount to receive the lock member, a remote control device operable from the bit mount and from adjacent the cutting edge exterior of the bit and to signal the electric drive arrangement.

The present invention also provides a tool lock having an integrated power locking and unlocking mechanism that can be independently and separately operated by wireless remote technology and thus does not require either a hammer or a hand tool to secure, for example, teeth or adapters to a ground engaging system.

The lock employs an internal motor and sensing system, operated by remote wireless technology such as Wi-Fi, bluetooth, RFID and/or other wireless transmission signals, to unlock and lock the mechanical hammerless locking system. The wireless transmission signal is transmitted via a handheld device, such as a mobile phone, tablet, remote control, and/or other such handheld device, for locking (installing) and unlocking (removing) the motorized locking system within the tool tip carrier and tool tip.

The motor, drive and electronic response circuits are all contained within the motorized locking device.

Thus, each electrically operated device comprises its own integrated motor, drive and lock member which is movable between locked and unlocked positions of the motor and which is contained within the body of each head carrier and/or adapter and is not accessible from the outside.

The locking assembly has a rebar or lock that is activated by a remote wireless signal and slides out of the assembly after the tooth or adapter is positioned, locking the tooth to the adapter, or locking the adapter to the shovel.

The wireless transmission signal is transmitted to a locking assembly that is housed, encapsulated and/or covered within an adapter nose or other bit mounting system. For example, there may be twenty or more such teeth and adapters on the shovel.

Each locking assembly will respond to a particular unique coded signal from the wireless transmitter device using the current coded signal system.

In this way, the operator can open one such locking device at a time.

Preferably, each lock member is operated by its own separate rack and pinion system driven by its own separate motor and battery. Of course, it should be understood that a shovel or other device may also have individual toothholders, adapters or connectors secured thereto, each having a suitable internal recess for receiving a power lock of the type described.

The present invention also provides a method of locking and unlocking a bit on a shovel.

The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and the specific objects attained by its uses, reference should be made to the accompanying drawings and descriptive matter in which there are illustrated and described preferred embodiments of the invention.

Drawings

FIG. 1 is an exploded view of an adapter, tooth and locking device;

FIG. 2 is a view corresponding to FIG. 1, showing the locking device exploded;

FIG. 3 is an enlarged exploded view of the locking device of FIG. 2;

FIG. 4 is a perspective view of the locking device;

FIG. 5 is an end elevational view of the locking device;

FIG. 6 is a cross-sectional view taken along line 6-6 of FIG. 5;

FIG. 7 is a cross-sectional view taken along line 7-7 of FIG. 1;

FIG. 8 is an enlarged detail view of circle 8 of FIG. 7; and

fig. 9 is a schematic perspective view of a shovel and a remote controller according to the present invention.

Detailed Description

As described above, the present invention provides an electric lock for an earth moving machine.

Such machines have some sort of scoop or scraper (fig. 9).

The blade of the shovel is provided with teeth.

To secure the teeth, the cutting edge will have a series of mounting members. These members may themselves be removable adapters or may be space welded to the blade. There may be twenty such mounting members on a shovel, the number of which depends on the size and design of such a shovel. These mounting members are typically provided with removable adapters. The tooth is then secured to the adapter. In most cases, the adapter and teeth are secured to the shovel by some type of lock or wedge. These typical locks or wedges are at least partially exposed to the external environment surrounding the tooth and adapter. Thus, during use of the shovel, these locks and wedges are subjected to extreme wear and stress when, for example, the shovel is moved into the soil and when the shovel turns the soil out. When the teeth or even the adapter are damaged or worn, replacement must be performed. This includes removing the wedges, discarding the damaged component and replacing the new component.

Often, the wedges themselves are damaged or difficult to remove.

In a typical shovel, there may be, for example, twenty individual adapters with twenty individual teeth. The locking means may adapt itself to both the locking of the adapter on the blade mounting member and the locking of the teeth on the adapter. The present invention provides a locking device for this purpose, i.e. locking the teeth to their adapters or locking the adapters to the tool mount on the shovel. Each locking device is concealed within the adapter or tooth or tool mount and is self-contained and has its own internal power mechanism.

The tooth and the adapter are formed by an internal cavity or recess. One of the cavities will receive a locking device inside the adapter or the mounting. The other tool, either the adapter or the tines themselves, are provided with internal sockets that align with internal cavities formed in the mount or adapter. By wireless remote technology, the locking means can be activated to lock the adapter on the mount or the tooth on the adapter. The locking device itself is completely hidden within the mount or adapter and is therefore protected from damage when used in the environment.

The internal electric mechanism incorporates known wireless technology and can be activated by a wireless remote control.

Fig. 1 shows an adapter (10) that may be generally secured to a support member on a shovel (fig. 9). The adapter (10) may be of the type which itself may be removed from the blade support member and replaced as required. The adapter (10) has a lock recess (12) to receive any suitable lock (not shown) by which the adapter can be locked to the shovel support member.

In this case, the adapter (10) is designed to support the teeth (14). The tooth (14) has a hollow interior (15) which is mounted on the front end (16) of the adapter (10). The front part (16) of the adapter has a body with a transverse cylindrical lock on one side for receiving a recess (18).

The adapter body has a longitudinal axis extending in a direction of movement of the scoop. The cylindrical lock receiving the recess is located on an axis perpendicular to the longitudinal axis. In this way the locking means will extend both outwards and inwards transversely of the axis of the adapter.

The recess (18) has an edge (20) with two linear portions.

The tooth (14) has a hollow body (15) with an internally concealed lock receiving seat (42) within the hollow body.

The locking device (24) is mounted within the interior recess (18) of the adapter (10).

The locking device (24) is shown in more detail in fig. 2 to 6.

The locking device (24) has a generally cylindrical body (26) defining a hollow interior (28). A partially cylindrical slide lock member (30) is slidable within the interior (28) of the body (26). The lock member (30) is connected to a linear rack (32) formed by gear teeth.

The drive gear (34) engages gear teeth on the gear rack (32). The gear (34) is driven by a motor (36). The motor (36) is controlled and powered by circuitry and batteries (38) located inside the main body (26).

The seal ring (40) is mounted on the main body (26) as required.

The tooth (14) has a hollow interior (15) mounted on the front end (16) of the adapter (10) (fig. 7). The tooth (14) is formed with an internal lock receiving seat (42) on one side of the hollow interior of the tooth (14) and is inaccessible from the exterior of the tooth (14). The socket (42) is positioned to align with the interior recess (18) of the adapter (10) and receive the lock member (30) when the tooth (14) is mounted on the front end (16) of the adapter (10).

Likewise, the socket (42) in the tooth is transversely aligned with the longitudinal axis of the tooth. Thus, when the tooth is mounted on the adapter, the recess (18) and the socket (42) are aligned with each other and transversely to the longitudinal axis of the tooth and the adapter.

A small diameter access bore (44) is formed in the adapter (10) and tooth (14) in alignment with each other. A bore (44) is connected to the inner end of the recess (18) to enable access to the locking means (24) by a service person from outside the tooth (14). It can thus be seen that the locking means (24) is completely concealed within the body of the adaptor (10) and the teeth (14) and is not exposed to the exterior of both. In this way, the service life of the locking device (24) is greatly extended and in practice it enables, through the operation of remote wireless technology, a quicker attention to the maintenance of the teeth on the shovel.

In operation, the locking device is first inserted into the cylindrical recess (18) of the adapter (10) with its locking member (30) retracted.

The tooth is then mounted on the front end (16) of the adapter (10). The teeth slide over the adapter (10) until the lock-receiving recess (18) is aligned with the lock-receiving seat (42). At this point, the locking device is completely hidden within and protected by the body of the adapter (10) and is not manually accessible from the exterior of the adapter (10) or the teeth (14). The motor (36) is then activated using the appropriate remote wireless device (W) (fig. 9). The gear (34) rotates and moves the lock member (30) out of the body (26). The lock member will enter the lock receiving seat (42) of the tooth (14), locking the tooth in place on the adapter.

To remove the teeth, the motor is started in reverse. This will cause the lock member (30) to retract the body (26) from the lock receiving seat (42) in the tooth.

The tooth can then be removed from the adapter.

The use of such a locking device (24) to lock the adapter to its shovel will involve substantially the same operation.

It should be understood that the described power lock is capable of connecting a removable attachment to a earthmoving machine, whether such removable device is a tooth adapter or a tooth itself, or other nature. In the claims, therefore, reference is made to a releasable cutter head, the intention being that the wording is common to both the adapter and the tooth itself.

Wireless techniques related to controlling each individual tooth lock are believed to be well known in the electronic arts and need not be described in particular detail. Of course, it will be appreciated that each lock should have its own unique signal. The operator of the device will have a handheld device (W) that can send a separate signal and code a specific tool lock on the device.

The process of the present invention is self-evident from the above.

Thus, the locking of the tooth on the adapter or the locking of the adapter on the support member on the shovel can be achieved by simply operating the hand-held device (W) and moving the locking member along an axis transverse to the axis of the tooth or adapter. This is accomplished without hammering the teeth or adapter, or attempting to operate a thread lock or wedge, as was the case with previous shovels.

When the recess (18) is shown in the adapter and the lock receptacle is in the tooth, this arrangement may be reversed in some cases.

It should also be understood that although reference has been made broadly to ground engaging systems and earth moving apparatus, the present invention is not necessarily limited to only earth moving apparatus. Other forms of electric shovels and lifting devices are also used, such as in cleaning construction sites or removing debris from collapsed buildings, to name a few.

The foregoing is merely a description of the preferred embodiments of the present invention and is, therefore, not limited to these embodiments.

The claims (modification according to treaty clause 19)

1. A shovel for an earth moving apparatus having a blade and a plurality of ground engaging teeth removably attached to the blade, characterized by:

a plurality of tooth holders located on the cutting edge;

a plurality of teeth releasably carried on respective said blocks, said teeth each defining a hollow interior cavity adapted to the respective said block;

a lock receiving recess in each of said tooth seats;

an electrically powered tooth lock received in a respective lock receiving recess, the electrically powered tooth lock including a movable lock member and an electrically powered drive operable to drive the respective lock member between two positions in response to a single coded signal;

a lock receiving receptacle accessible within the hollow interior of each tooth and oriented to a position corresponding to the respective lock receiving recess; and the number of the first and second groups,

a remote control device capable of wirelessly transmitting respective coded signals to the respective electric drive devices to operate the respective electric drive devices in the respective electric tooth locks.

2. The shovel for an earth moving apparatus of claim 1, further characterized by a drive gear rack attached to each of the movable lock members, a drive gear connected with the gear rack, a motor coupled to the drive gear, the motor located within the motorized tooth lock.

3. The shovel for an earth moving apparatus of claim 2 further characterized in that the motorized tooth lock is fully contained within the block, wherein the movable lock member is movable by remote operation of the motor and the drive gear to move the lock member in and out of engagement in the lock receptacle in the tooth.

4. The shovel for an earth moving apparatus of claim 3, further characterized in that the block is fixedly secured to the shovel.

5. The shovel for an earth moving apparatus of claim 3, further characterized by a plurality of tooth adapters removably attached to respective ones of the tooth mounts.

6. The shovel for an earth moving apparatus of claim 3, further characterized in that a respective tooth is mounted on a respective tooth holder on the shovel.

7. The shovel for an earth moving apparatus of claim 3, further characterized in that the lock-receiving recesses are formed in a side portion of the block and along an axis perpendicular to a longitudinal axis of each of the blocks, and wherein the lock-receiving receptacles are formed inside each of the teeth, aligned along an axis perpendicular to a longitudinal axis of each of the teeth, and positioned to align with the respective lock-receiving recesses in the blocks as the teeth slide over the blocks.

8. A remotely operated power tooth lock for securing a plurality of individual teeth to respective independent tooth mounts on a ground engaging system, each said tooth lock being completely concealed within a respective pair of tooth mount and tooth, characterized in that:

a lock housing body adapted to be placed in one of the teeth and the tooth holder of the ground engaging system;

a lock member slidably secured in the lock housing body;

a drive transmission connected to the lock member operable to extend and retract the lock member relative to the lock housing body;

a wireless response motor operable to respond to a single coded wireless transmission to control the drive transmission means; and the number of the first and second groups,

a remote wireless controller operable to send a specific respective coded signal to each respective said tooth lock and to operate its respective said wireless responsive motor.

9. The remotely operated power tooth lock according to claim 8, further characterized in that the tooth holder defines a lock receiving recess, and wherein the teeth define a hollow interior that fits into the holder and a lock receiving receptacle accessible within the hollow interior of the teeth for receiving the lock member from the lock housing body.

10. The remotely operated electrically powered tooth lock of claim 9 further characterized in that the lock member is attached to a gear bar and includes a drive gear engaged with the gear bar, the drive gear being responsive to operation of the motor to extend and retract the lock member relative to the lock housing body.

11. The remotely operated electrically powered tooth lock according to claim 10 further characterized in that said tooth holder is fixedly secured to said ground engaging system.

12. The remotely operated power tooth lock according to claim 11, further characterized by a tooth adapter removably attached to the respective tooth holder.

13. The remotely operated electrically powered tooth lock according to claim 12 further characterized in that respective teeth are mounted on respective said tooth adapters.

14. The remotely operated power tooth lock of claim 8, including a lock receiving recess formed in each of said tooth mounts, said lock receiving recess being formed in a side portion of said tooth mount and along an axis perpendicular to a longitudinal axis of each of said tooth mounts, wherein said lock receiving recess is formed in an interior of each of said teeth, is aligned along an axis perpendicular to a longitudinal axis of said teeth, and is positioned to align with a corresponding said lock receiving recess in said tooth mount when said teeth are slid over said tooth mounts.

15. A method of remotely securing a tooth to a tooth holder on a ground-engaging shovel, comprising:

forming the block with an inner lock receiving recess;

a tooth formed with a hollow interior defining a lock-receiving receptacle;

placing a tooth lock in the recess of the block, the tooth lock having a lock member slidably secured in a lock housing body and operable in response to an internally positioned motor to move the lock member,

placing teeth defining a hollow interior above the block and the tooth lock, the teeth defining a hollow interior having a lock receptacle,

aligning the lock receptacle with the tooth lock housing recess in the tooth holder, an

A step of operating said wireless responsive motor by a remote wireless controller external to said toothholder and said tooth.