The present invention relates to power tools, and more particularly to concrete vibrators.
Concrete vibrators are typically used to spread poured concrete around a framework, such as rebar, in a construction operation. Such concrete vibrators are typically powered by an internal combustion engine, which can be difficult to carry by an operator using the concrete vibrator while on a worksite.
The invention provides, in one aspect, a concrete vibrator including a housing, a handle, an electric motor, a flexible shaft, a vibrator head, and a battery pack. The handle extends from the housing. The electric motor is coupled to the housing. The flexible shaft has a first end coupled to the motor and an opposite, second end. The vibrator head is coupled to the second end of the shaft. The vibrator head is configured to receive torque from the motor and the shaft to cause the vibrator head to vibrate. The battery pack is coupled to a battery receptacle defined on the housing. The battery pack is configured to provide electric power to the electric motor to drive the motor and the shaft. The concrete vibrator is operable in a briefcase configuration in which the handle is used to carry the concrete vibrator with the housing supported in a horizontal orientation.
The invention provides, in another independent aspect, a concrete vibrator including a housing, a handle, an electric motor, a flexible shaft, a vibrator head, a battery pack, and a remote control unit. The handle extends from the housing. The electric motor is coupled to the housing. The flexible shaft has a first end coupled to the motor and an opposite, second end. The vibrator head is coupled to the second end of the shaft. The vibrator head is configured to receive torque from the motor and the shaft to cause the vibrator head to vibrate. The battery pack is coupled to a battery receptacle defined on the housing. The battery pack is configured to provide electric power to the electric motor to drive the motor and the shaft. The remote control unit is capable of adjusting the operation of the motor to adjust a vibration frequency of the vibrator head while the concrete vibrator is operated in a briefcase configuration in which the handle is used to carry the concrete vibrator with the housing supported in a horizontal orientation.
The invention provides, in another independent aspect, a concrete vibrator including a housing, a handle, an electric motor, a flexible shaft, a vibrator head, and a battery pack. The handle extends from the housing. The electric motor is coupled to the housing. The flexible shaft has a first end coupled to the motor and an opposite, second end. The vibrator head is coupled to the second end of the shaft. The vibrator head is configured to receive torque from the motor and the shaft to cause the vibrator head to vibrate. The battery pack is coupled to the battery receptacle defined on the housing. The battery pack is configured to provide electric power to the electric motor to drive the motor and the shaft. The concrete vibrator is operable in a briefcase configuration in which at least one of the base portion and the handle portion is used to carry the concrete vibrator in a horizontal orientation. The electric motor has a power output of at least 2760 W and a nominal outer diameter of up to about 80 mm. The battery pack has a nominal voltage of about 80 V.
Other features and aspects of the invention will become apparent by consideration of the following detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
The concrete vibrator 10 also includes a flexible shaft 26 extending from the housing 14 and a vibrator head 30 connected to an end of the shaft 26. As explained in further detail below, the shaft 26 receives torque from the motor 18. The torque is transmitted to the vibrating head 30, causing it to vibrate. With reference to
When the concrete vibrator 10 is carried by a user in the backpack configuration shown in
In the illustrated embodiment of the concrete vibrator 10, the shaft 26 extends upward from the top surface 42 of the housing 14, is bent into a “U” shape, and redirected downward for the vibrating head 30 to be grasped by the user. In other embodiments, the flexible shaft 26 may protrude from a downward-inclined surface (embodiment of
In yet another embodiment, the flexible shaft 26 may extend from a bottom surface 50 of the housing 14 when the vibrator 10 is carried in the backpack configuration. In this embodiment, the flexible shaft 26 protrudes from the bottom surface 50 of the housing 14 in a direction towards the ground when a user supports the vibrator with the straps 34. Notably, in this embodiment, as well as the embodiment shown in
With reference to
Optionally, the concrete vibrator 10 may include one or more hooks 56 extending from one of the side-facing surfaces 46 of the housing 14.
As shown in
With reference to
The remote control unit 102 is more clearly shown in
Additionally or alternatively, the remote control unit 102 is capable of controlling the speed of the motor 18 with a joystick 110 on the remote control unit 102. Input from the joystick 110 may be transmitted wirelessly to the motor control unit of the concrete vibrator 10 to adjust the speed of the motor 18. In some embodiments, the joystick 110 may be toggled in a first direction (e.g., toward the right from the frame of reference of
The concrete vibrator 10 may be provided with one or more work lights 104 (shown schematically in
The remote control unit 102 includes an onboard rechargeable power source (i.e., a battery, not shown). As such, the remote control unit 102 may be charged by connection with a receptacle onboard the concrete vibrator 10 or another tool with which the battery pack 22 is interchangeable. Alternatively, the remote control unit 102 may be charged via a USB cable, through an inductive charger, or through another charging means with the battery remaining onboard the remote control unit 102. As a further alternative, the remote control unit 102 may contain a removable battery capable of being charged with a separate charger.
The remote control unit 102 may utilize one of many methods to communicate with the concrete vibrator 10. For example, at least BTLE, standard Bluetooth, radio frequency communication such as 433 MHz, Wi-Fi, infrared, or standard cellular communication frequencies (2G, 3G, 4G, 5G, or LTE services) provide adequate communication methods between the remote control unit 102 and the concrete vibrator 10. The remote control unit 102 may include a transmitter 126 configured to send messages to a receiver 130 on the concrete vibrator 10 (
Additionally or alternatively, a signal may be generated by the controller 103 of the concrete vibrator 10 to indicate the running state (i.e., on/off status, direction, and speed) of the motor 18. This signal may be sent by a transmitter 134 of the concrete vibrator 10 and may be received by a receiver 138 of the remote control unit 102 for communicating the signal to the user via an indicator 142 on the remote control unit 102. Thus, the indicator 142 may communicate to a user of the concrete vibrator 10 the running state of the motor 18. In the illustrated embodiment, the indicator 142 is an LED configured to illuminate, for example, when the motor 18 is activated. Alternatively or additionally, the indicator 142 may provide an audible or tactile signal to the user.
When using the remote control unit 102, a first user carrying the concrete vibrator 10 may be responsible for submerging and moving the head 30 throughout a region of wet concrete, while a second user may hold the remote control unit 102 and be responsible for adjusting the frequency of vibration of the head 30 to account for variations in the consistency of the wet concrete, or to adjust the vibrator head 30 for use with wet concrete in different stages of dryness. In this manner, the user carrying the vibrator 10 needs only to concentrate on placement of the head 30 within the wet concrete. Alternatively, the same user responsible for submerging and moving the head 30 may also hold the remote control unit 102 and be responsible for adjusting the frequency of vibration of the head 30. This allows a single user to adjust the frequency of vibration of the head 30 based on tactile feedback from the vibrating head due to the consistency of the wet concrete. Additionally or alternatively, a single user can operate the concrete vibrator 10 by submerging the head 30 in wet concrete and controlling the frequency of vibration of the head 30 using the remote control unit 102, all while carrying the concrete vibrator 10 with the straps 34.
In operation, the vibrator head 30 can be submerged in wet concrete and the remote control unit 102 can allow a user or users of the concrete vibrator 10 to adjust the frequency of vibration of the vibrator head 30 without requiring a user to carry the concrete vibrator 10. Optionally, during operation, a user can hold the concrete vibrator 10 with the straps 34, 38 in a backpack configuration (see e.g.,
With reference to
With reference to
The frame 254 is shaped such that a user or multiple users can hold the frame 254 at opposite sides of the frame 254 adjacent to the housing 214 and the motor 218, respectively. The frame 254 includes a base portion 255 to which the main housing 214 is coupled. The frame 254 further includes a first handle portion 256A extending from one end of the base portion 255 and configured to be grasped by a user while transporting the concrete vibrator 210 in the briefcase configuration. The frame 254 further includes a second handle portion 256B extending from an end of the base portion 255 opposite the first handle portion 256B. The second handle portion 256B is alternately graspable by a user while transporting the concrete vibrator 210 in the briefcase configuration. The back plate 346 is fastened to the base portion 255 of the frame 254. With reference to
Alternatively, as illustrated in
With reference to
With continued reference to
In the embodiment illustrated in
Finally, the housing 214 of the concrete vibrator 210 has a storage receptacle 370 in which the remote control unit 302 can be stored when not in use (
In an alternative embodiment, the vibrating head 30 houses the motor 18 within the head 30. This alternative embodiment may be applied to either the concrete vibrator 10 or the concrete vibrator 210. In this embodiment, a power cord runs from the housing 14 through or along the shaft 26 (which, in this alternative embodiment, is merely configured as an outer jacket for protecting the power cord) to the motor 18. In the previously discussed embodiments, the flexible shaft 26 transmits torque from the motor 18 to the head 30. However, in this alternative embodiment, the motor 18 is located in the head 30, and the shaft 26 provides protection for the power cord connecting the housing 14 and the motor 18.
In another alternative embodiment, the motor 18 is located in the middle region of the shaft 26. In other words, the motor 18 may be located in-line with the shaft 26, with the motor 18 receiving electrical power at one end and transmitting torque at the other end. This alternative embodiment may be applied to either the concrete vibrator 10 or the concrete vibrator 210. The motor 18 may receive power from a power cord extending from the housing 14 to the middle region of the shaft 26 (which, in this alternative embodiment, is partially configured as an outer jacket for protecting the power cord). Then, a flexible shaft may extend within the shaft 26 between the motor 18 and the head 30 to rotate the eccentric shaft 70. Such a configuration may be beneficial during use of the concrete vibrator 10 in the briefcase configuration as the in-line configuration provides a lighter and more flexible section between the middle region of the shaft 26 and the housing 14. This lighter and more flexible section may induce less fatigue to a user during use. The lighter and more flexible section of the shaft 26 may be more maneuverable when compared to the previously discussed embodiments having a torque transmitting shaft extending the entire length of the shaft 26.
Various features of the invention are set forth in the following claims.
This application is a continuation of co-pending U.S. patent application Ser. No. 16/953,612 filed on Nov. 20, 2020, which claims priority to U.S. Provisional Patent Application No. 62/937,840 filed on Nov. 20, 2019, the entire contents of both of which are incorporated herein by reference.
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Makita “XRV01Z 18V LXT® Lithium-Ion Cordless 4′ Concrete Vibrator, Tool Only” <https://www.makitatools.com/products/details/XRV01Z> web page publicly available at least as early as Jul. 23, 2019 (2 pages). |
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Number | Date | Country | |
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Parent | 16953612 | Nov 2020 | US |
Child | 17888659 | US |