CN218922402U - Vacuum cleaner assembly - Google Patents

Abstract

A vacuum cleaner assembly includes an upright vacuum cleaner, a hand-held accessory, and a battery. An upright vacuum cleaner includes a cleaning head, an upright frame, and a first battery holder. The upright frame is pivotally connected to the cleaning head. The first battery holder is connected to at least one of the upright frame or the cleaning head. The hand-held accessory includes an auxiliary battery mount. The hand-held accessory is detachably coupled to the upright frame. The battery is removably coupled to the first battery mount to power the upright vacuum cleaner and removably coupled to the second battery mount to power the handheld accessory.

Description

Vacuum cleaner assembly

Cross Reference to Related Applications

The present application claims priority from U.S. provisional patent application No. 62/956,755, filed 1/3/2020, the entire contents of which are incorporated herein by reference.

Background

The present disclosure relates to a vacuum cleaner assembly. In particular, the present disclosure relates to a vacuum cleaner assembly including an upright vacuum cleaner and a hand-held accessory.

Disclosure of Invention

In one embodiment, the present disclosure provides a vacuum cleaner assembly comprising an upright vacuum cleaner, a handheld accessory, and a battery. An upright vacuum cleaner includes a cleaning head, an upright frame, and a first battery holder. The upright frame is pivotally connected to the cleaning head. The first battery holder is connected to at least one of the upright frame or the cleaning head. The hand-held accessory includes an auxiliary battery mount. The hand-held accessory is detachably coupled to the upright frame. The battery is removably coupled to the first battery mount to power the upright vacuum cleaner and removably coupled to the second battery mount to power the handheld accessory.

In another embodiment, the present disclosure provides a vacuum cleaner assembly comprising an upright vacuum cleaner, a handheld accessory, and a battery. The upright vacuum cleaner includes a first battery holder. The hand-held accessory includes a second battery holder. The hand-held accessory is removably coupled to the upright vacuum cleaner. The battery is detachably coupled to the first battery holder and detachably coupled to the second battery holder. When the battery is coupled to the first battery holder, the battery only powers the upright vacuum cleaner. When the battery is coupled to the second battery mount, the battery only powers the handheld accessory.

In another embodiment, the present disclosure provides a vacuum cleaner assembly comprising an upright vacuum cleaner and a handheld accessory. The upright vacuum cleaner includes a first motor and a first battery connection terminal. The first battery connection terminal electrically couples the first motor to the battery. The hand-held accessory is removably coupled to the upright vacuum cleaner. The handheld accessory includes a second motor and a second battery connection terminal. The second battery connection terminal electrically couples the second motor to the battery.

Before any embodiments of the disclosure are explained in detail, it is to be understood that the disclosure 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 disclosure is capable of other embodiments and of being practiced or of being carried out in various ways. Other aspects of the disclosure will become apparent by consideration of the detailed description and accompanying drawings.

Drawings

Figure 1 illustrates a perspective view of a vacuum cleaner assembly according to embodiments described herein.

Figure 2 shows a detailed perspective view of the vacuum cleaner assembly of figure 1 with the hand-held accessory and battery exploded from the upright vacuum cleaner.

Figure 3 illustrates a cross-sectional view of the vacuum cleaner assembly taken along line 3-3 of figure 1.

Figure 4 shows a detailed perspective view of the vacuum cleaner assembly of figure 1 with the hand-held accessory, adapter and battery exploded from the upright vacuum cleaner and the optional handle shaft exploded from the upright vacuum cleaner.

Figure 5 shows a front perspective view of an adapter of the vacuum cleaner assembly of figure 1.

Fig. 6 illustrates a rear perspective view of the adapter of fig. 5.

Fig. 7 illustrates a side elevation view of the adapter of fig. 5.

Figure 8 shows a perspective view of the vacuum cleaner assembly of figure 1 with an additional battery.

Figure 9 shows a rear perspective view of the hand-held accessory of the vacuum cleaner assembly of figure 1.

Fig. 10 illustrates an exploded rear perspective view of the handheld accessory of fig. 9.

Fig. 11 illustrates a cross-sectional side view of the handheld accessory taken along line 11-11 of fig. 9.

FIG. 12 illustrates a perspective view of the dirt cup of the handheld accessory of FIG. 1 with the shroud exploded from the dirt cup.

Figure 13 illustrates a rear elevational view of the dirt cup of figure 12.

Fig. 14 illustrates a cross-sectional view of the shroud taken along line 14-14 of fig. 12.

Figure 15 illustrates an exploded rear perspective view of another embodiment of a handheld accessory of the vacuum cleaner assembly of figure 1.

Fig. 16 shows a detailed perspective view of the filter access door in a closed position with the latch disengaged from the housing of the handheld accessory of fig. 15.

Fig. 17 shows a detailed perspective view of fig. 16 with the filter access door partially detached from the housing.

Fig. 18 shows a detailed perspective view of fig. 16 with the filter access door completely removed from the housing.

Fig. 19 shows a detailed partial cutaway perspective view of the handheld accessory of fig. 15 with the filter access door removed.

Fig. 20 shows a detailed partial cutaway perspective view of fig. 19 with the filter removed from the housing.

Fig. 21 shows a cross-sectional side view of the handheld accessory of fig. 15.

Fig. 22 illustrates an exploded side perspective view of the handheld accessory of fig. 15.

FIG. 23 illustrates a perspective view of the dirt cup of the handheld accessory of FIG. 15 with the shroud exploded from the dirt cup.

FIG. 24 illustrates a rear elevational view of the dirt cup of FIG. 23.

Fig. 25 shows a cross-sectional view of the shield taken along line 25-25 of fig. 23.

Detailed Description

Referring to fig. 1, a vacuum cleaner assembly 100 is shown. The vacuum cleaner assembly 100 includes an upright vacuum cleaner 102, a handheld accessory 104, and a battery 106. In some embodiments, the vacuum cleaner assembly 100 further includes an adapter 108 that removably couples the handheld accessory 104 to the upright vacuum cleaner 102. In some embodiments, the battery 106 may be used interchangeably between the vacuum cleaner 102 and the handheld accessory 104. This interchangeability may allow a user to purchase/own only one battery 106 for a variety of cleaning applications. Further, this interchangeability may reduce the overall weight of the vacuum cleaner assembly 100, as only one battery 106 need be included.

As shown in FIG. 1, the upright vacuum cleaner 102 includes a cleaning head 110, an upright frame 112 pivotally connected to the cleaning head 110, and a dirt cup 114. The upright frame 112 includes a pivot end 116 and a hand-held end (or engagement end) 118 opposite the pivot end 116. The cleaning head 110 is pivotally connected to the upright frame 112 near the pivot end 116. The upright frame 112 defines a longitudinal axis A1 extending through the pivot end 116 and the hand end 118. The upright frame 112 also includes a front surface 120 (fig. 1) and a rear surface 122 (fig. 2) opposite the front surface 120. During operation, the front surface 120 is located forward of the rear surface 122 in a forward direction of the upright vacuum cleaner 102.

Referring to fig. 2, the upright vacuum cleaner 102 further includes a first battery holder 124. The first battery holder 124 is shown connected to the upright frame 112, but the first battery holder 124 may alternatively be connected to the cleaning head 110. The first battery holder 124 includes a first battery connection terminal 126. In the embodiment shown in fig. 2, the first battery holder 124 includes a plurality of first battery connection terminals 126. The battery 106 is detachably coupled to the first battery holder 124. In some embodiments, the battery 106 is slidably received on the first battery mount 124 in a direction extending along the longitudinal axis A1 of the upright frame 112. In the illustrated embodiment, the battery 106 is slidably received on the first battery mount 124 in a direction extending parallel to the longitudinal axis A1. With the battery 106 detachably coupled to the first battery mount 124 and electrically coupled to the first battery connection terminal 126, the battery 106 powers at least one operating component of the upright vacuum cleaner 102. The operating component may be, for example, a suction motor, a brushroll motor, a pump, a valve, an actuator, a microprocessor, a controller, or other operating component.

As shown in fig. 3, the upright vacuum cleaner 102 further includes a first operating member that is a first motor 128. The first motor 128 drives a first impeller (not shown) to generate an air flow. In embodiments including a first motor 128 driving the first impeller, the first motor 128 may also be considered a first suction motor. With the battery 106 coupled to the first battery mount 124 and electrically coupled to the first battery connection terminal 126, the first motor 128 is electrically coupled to and powered by the battery 106.

As also shown in FIG. 3, a flow channel or first air flow path 130 passes through the cleaning head 110 and is in fluid communication with the dirt cup 114. This flow channel 130 is isolated from the handheld accessory 104. The first motor 128 generates suction to draw air and dirt through the flow passage 130 and into the dirt cup 114. The dirt separator within the dirt cup 114 separates dirt and debris from the incoming air flow, collects the separated dirt within the dirt collection chamber, and directs the clean air to the motor 128 from which it is discharged into the environment. In the illustrated embodiment, the dirt separator is a cyclonic dirt separator. The dirt cup 114 is removable and includes a bottom door that is selectively openable by pivoting to empty debris from the dirt collection chamber when the chamber is full.

As shown in fig. 4, the upright vacuum cleaner 102 further includes a connection post 132 coupled to the upright frame 112. In some embodiments, the connection post 132 is integrally formed with the upright frame 112. In the illustrated embodiment, the connection post 132 is detachably coupled to the upright frame 112. The connection post 132 includes a proximal end 134 that is received within a connection opening 136 of the upright frame 112. The connecting post 132 further includes a distal end 138 opposite the proximal end 134.

In some embodiments, the vacuum cleaner assembly 100 further includes a handle attachment 140 that is detachably coupled to the upright vacuum cleaner 102. The handle attachment 140 includes a handle 142 and a handle shaft 144 coupled to the handle 142. In the illustrated embodiment, the handle shaft 144 is detachably coupled to the connection post 132. However, in some embodiments, the handle shaft 144 is removably coupled into the connection opening 136 of the upright frame 112.

In some embodiments, the connection post 132 includes one or more fasteners for detachably coupling the connection post 132 to the adapter 108 or the handle attachment 140. The fastener may include, for example, one or more stop mechanisms. These fasteners pass through one or more through holes 146 defined in the connecting post 132. In some embodiments, the adapter 108 is not detachable from the connection post 132 and is integral with or otherwise secured to the connection post 132.

Figure 4 also shows that the vacuum cleaner assembly 100 further comprises an adapter 108 that is detachably coupled to the upright vacuum cleaner 102. In some embodiments, the adapter 108 is formed as a single, unitary piece. Adapter 108 is also detachably coupled to handheld accessory 104. In the illustrated embodiment, the vacuum cleaner assembly 100 is arranged such that only one of the handle shaft 144 and the adapter 108 can be detachably coupled to the upright vacuum cleaner 102 at a time.

Referring to fig. 5-7, the adapter 108 includes an adapter body having an upright vacuum cleaner engagement end 148 configured to connect the adapter 108 to a portion of the upright vacuum cleaner 102. In the illustrated embodiment, the upright vacuum cleaner engagement end 148 has a recess 150 defined therein. The recess 150 is sized to removably receive the distal end 138 of the connecting post 132. The adapter 108 further includes a hand-held accessory engagement end 152 opposite the upright vacuum cleaner engagement end 148. The hand-held accessory engagement end 152 includes a tab 154. In other words, the protrusion 154 is positioned opposite the recess 150. The longitudinal axis A2 of the adapter 108 extends through the upright vacuum cleaner engagement end 148 and the hand-held accessory engagement end 152. In the illustrated embodiment, the recess 150 is open in a direction extending along the longitudinal axis A2. The protrusion 154 also extends in a direction along the longitudinal axis A2. In some embodiments, the longitudinal axis A2 extends along the longitudinal axis A1 such that the protrusion 154 also extends away from the upright frame 112 along the longitudinal axis A1. In some embodiments, at least a portion of the free end of the protrusion 154 is tapered.

The adapter 108 further includes an outer peripheral wall 156 surrounding the adapter body between the hand-held accessory engagement end 152 and the upright vacuum cleaner engagement end 148, which peripheral wall surrounds the recess 150 and extends in a direction along the longitudinal axis A2. The illustrated peripheral wall 156 includes a first peripheral wall portion 158 and a second peripheral wall portion 160. The first peripheral wall portion 158 is longer along the longitudinal axis A2 than the second peripheral wall portion 160. In the illustrated embodiment, this difference in length creates an angled recess 150 to match the profile of the upright frame 112.

The peripheral wall 156 further includes at least one aperture 162 defined therein. At least one hole 162 receives a fastener therethrough, thereby coupling the adapter 108 to the connection post 132. In some embodiments, when the adapter 108 is coupled to the connection post 132, a stop mechanism coupled to the connection post 132 at least partially occupies the aperture 162.

The peripheral wall 156 also has an adapter outer surface 164. The adapter outer surface 164 is arranged in a stepped configuration relative to the protrusion 154 such that the shoulder 166 extends laterally between the protrusion 154 and the adapter outer surface 164. In the illustrated embodiment, the shoulder 166 surrounds the protrusion 154. It is also shown in the illustrated embodiment that at least a portion of the shoulder 166 is oblique relative to a direction extending perpendicular to the longitudinal axis A2 of the adapter 108.

The adapter 108 also includes a retainer member 168. The retainer member 168 extends in a direction along the protrusion 154. In some embodiments, the retainer member 168 is aligned with the second peripheral wall portion 160 in a direction along the longitudinal axis A2 of the adapter 108. In the illustrated embodiment, the retainer member 168 extends parallel to the protrusion 154. The retainer member 168 includes at least one tooth 170 extending toward the tab 154. The retainer member 168 also includes a user engageable actuator, such as a tab 172. The user may engage the tab 172 or another user-engageable actuator to move the at least one tooth 170 away from the protrusion 154, such as by sliding or pivoting movement. In the illustrated embodiment, the retainer member 168 and teeth 170 pivot together away from the protrusion 154. In some embodiments, the teeth 170 are movable relative to the retainer member 168. The tab 172 extends in a direction away from the protrusion 154. In the illustrated embodiment, a gap 174 is defined between the teeth 170 and the protrusion 154. User engagement of the at least one tooth 170 moving away from the protrusion 154 widens the gap 174. In some embodiments, the teeth 170 move against the force of a spring or other resilient member configured such that the spring urges the teeth 170 toward their rest or seating position.

Returning to fig. 2, the vacuum cleaner assembly 100 further includes a handheld accessory 104 removably coupled to the upright frame 112. In the illustrated embodiment, a handheld accessory (shown as a handheld vacuum cleaner) 104 is coupled to an adapter 108, which in turn is coupled to an upright frame 112. The handheld accessory 104 is coupled to the upright frame 112 at a location closer to the handheld end 118 than the pivot end 116. Specifically, when the handheld accessory 104 is coupled to the upright frame 112, the handheld accessory 104 protrudes beyond the handheld end 118 of the upright frame 112 in a direction away from the pivot end 116.

The handheld accessory 104 includes a handle 176 having a gripping portion. With the handheld accessory 104 coupled to the upright frame 112, the handle 176 acts as a handle for the upright vacuum cleaner 102. In the event that the handheld accessory 104 is detached from the upright frame, the handle 176 acts as a handle for the handheld accessory 104. In the illustrated embodiment, the handle 176 is a pistol grip handle.

The handheld accessory 104 further includes an elongated structural member 178 having a nozzle or nozzle end 180. The handle 176 of the handheld accessory 104 is opposite the nozzle end 180, and the handle 176 extends at an angle relative to the longitudinal axis A3 of the elongate structural member 180. In the illustrated embodiment, the elongate structural member 178 includes a body portion 178A extending from the nozzle end 180 and a tang portion 178B extending from the body portion 178A and into the gripping portion of the handle 176. In some embodiments, the elongate structural member 178 is a continuous, unitary piece.

In the illustrated embodiment, the handle 176 of the handheld accessory 104 extends in a direction that is at an angle of about 45 degrees relative to the longitudinal axis A3. In some embodiments, the handle 176 extends in a direction at an angle between 10 and 90 degrees, more specifically between 30 and 60 degrees, relative to the longitudinal axis A3. With the handheld accessory 104 connected to the upright frame 112, the handle 176 extends at an angle relative to the longitudinal axis A1 of the upright frame 112. To connect the handheld accessory 104 to the adapter 108, at least a portion of the protrusion 154 is removably received in the nozzle end 180. As such, when the handheld accessory 104 is coupled to the upright frame 112, the suction nozzle 180 is substantially blocked.

As shown in fig. 3, with the protrusion 154 received in the nozzle end 180, the retainer member 168 engages the handheld accessory 104. In the illustrated embodiment, the at least one tooth 170 engages the handheld accessory 104 (shown in fig. 2) by entering a corresponding cavity 182 defined in an elongate structural member outer surface 184 of a channel wall 186 of the elongate structural member 178. A channel wall 186 extends from the spout end 180, and at least a portion of the channel wall 186 includes a channel wall thickness 188 that is thicker than the gap 174 between the tooth 170 and the protrusion 154. In the illustrated embodiment, this thickness differential forces the at least one tooth 170 into engagement with the handheld accessory 104. The at least one tooth 170 is forced into engagement with the handheld accessory 104 by a resilient member (such as a spring) or by flexing the retainer member 168 such that the retainer member 168 exhibits a restoring force. To detach the handheld accessory 104 from the adapter 108 in the illustrated embodiment, a user actuates the tab 172 to move the retainer member 168 to disengage the at least one tooth 170 from the handheld accessory 104.

In the illustrated embodiment, the adapter 108 and the handheld accessory 104 are sized such that the adapter outer surface 164 is substantially flush with the elongated structural member outer surface 184. In other words, these surfaces 164, 184 form a substantially tangential transition. The suction nozzle 180 is further inclined in a manner matching the inclination of the shoulder 166. In the illustrated embodiment, the handheld accessory 104 is further coupled to the upright frame 112 such that the elongate structural member 178 is closer to the front surface 120 than the rear surface 122. In some embodiments, at least a portion of the elongate structural member outer surface 184 is substantially aligned with the front surface 120 of the upright frame 112. This surface continuity between the upright frame 112, adapter 108, and handheld accessory 104 is aesthetically pleasing and serves to make the vacuum cleaner assembly 100 sturdy and aesthetically pleasing.

When the handle 176 of the handheld accessory 104 serves as the handle of the upright vacuum cleaner 102, the force applied to the handle 176 for maneuvering the upright vacuum cleaner 102 is transferred through the elongated structural member 178, the nozzle end 180, and the adapter 108 to the upright frame 112. The novel improvements disclosed in connection with the continuous elongated structural member 178 extending from the nozzle end 180 into the gripping portion of the handle 176 and the protrusion 154 being removably received in the nozzle end 180 provide a strong connection between the user-manipulable grip and the upright frame 112 while achieving the desired appearance over prior art connections. In some embodiments, the assembled vacuum cleaner assembly 100 resembles a single upright vacuum cleaner without an accessory, while still providing a detachable hand-held accessory 104.

Referring to fig. 2, the handheld accessory 104 further includes a second battery holder 190. In the illustrated embodiment, the second battery holder 190 is identical to the first battery holder 124. As such, the second battery holder 190 includes at least one second battery connection terminal 192. The battery 106 is detachably coupled to the second battery holder 190 to power at least one operating component of the handheld accessory 104. The operating component may be, for example, a suction motor, a brushroll motor, a pump, a valve, an actuator, a microprocessor, a controller, or other operating component. In some embodiments, the battery 106 is slidably received on the second battery holder 190 in a direction along the longitudinal axis A3 of the elongate structural member 178. In the illustrated embodiment, the battery 106 is slidably received on the second battery holder 190 in a direction extending parallel to the longitudinal axis A3.

As shown in fig. 3, the handheld accessory 104 also includes a second operating member that is a second motor 194. The second motor 194 drives a second impeller (not shown) to generate an air flow. In embodiments including a second motor 194 that drives the second impeller, the second motor 194 may also be considered a second suction motor. When the battery is coupled to the second battery mount 190 and electrically coupled to the at least one second battery connection terminal 192, the second motor 194 is electrically coupled to and powered by the battery 106.

When the battery 106 is coupled to the first battery mount 124, only the first motor 128 is electrically coupled to the battery 106; the second motor 194 does not receive electric power. When the battery 106 is coupled to the second battery mount 190, only the second motor 194 is electrically coupled to the battery 106; the first motor 128 does not receive electric power. In other words, the battery 106 only powers one of the first motor 128 (when the battery 106 is coupled to the first battery mount 124) and the second motor 194 (when the battery 106 is coupled to the second battery mount 190) at a time, interchangeable between the vacuum cleaner 102 and the handheld accessory 104.

As shown in fig. 8, in some embodiments, a second battery 106B is provided that is interchangeable with the battery 106, and the first and second battery holders 124, 190 are configured to receive one of the battery 106 and the second battery 106B. Providing an on-board second battery 106B that is interchangeable with the battery 106 enables a user to, for example, replace the second battery 106B with the battery 106 when the battery 106 is depleted, thereby extending the continuous operation time of the vacuum cleaner assembly 100. Also, providing an on-board second battery 106B enables a user to use both the upright vacuum cleaner 102 and the handheld accessory 104 without having to replace the batteries 106, 106B. The second battery 106B may be substantially a replica of the battery 106 having the same battery characteristics. In some embodiments, the battery 106 has different features than the second battery 106B. For example, and without limitation, the battery 106 may have a first battery capacity (e.g., 2A-h) and the second battery 106B may have a second battery capacity (e.g., 4A-h). The feature may further be any one or any combination of voltage, current, resistance, number of cells, etc.

Referring to fig. 3, in some embodiments, the handheld accessory 104 further includes a second air flow path 196. When the handheld accessory 104 is coupled to the adapter 108, the second airflow path 196 is substantially blocked. The first air flow path 130 and the second air flow path 196 are separate and discrete from each other regardless of whether the handheld accessory 104 is coupled to the upright frame 112.

As shown in fig. 9, the handheld accessory 104 acts as a stand-alone device when detached from the adapter 108 (and/or upright frame 112) and when assembled with the battery 106. In the illustrated embodiment, the handheld accessory 104 is a handheld vacuum accessory, but other embodiments may include alternative accessories. Such alternative accessories include powered bristle brushes, wherein the operating member is a brush motor or other operating member; a powered upholstery or stair cleaning implement wherein the operating component is a brush motor, suction motor or other operating component; a powered cleaning liquid injector wherein the operating component is a pump, valve or other operating component; a drill, wherein the operating component is a drill motor or other operating component; a flashlight in which the operating component is a light or other operating component; or any other power tool and operating components.

Referring to fig. 10 and 11, the handheld accessory 104 includes a housing 198, a motor (or second motor) 194, a filter access door 200, a filter 202, a dirt cup 204, and a shroud 206. Housing 198 includes a top 208, a bottom 210 opposite top 208, a front 212, and a rear 214 opposite front 212. The housing 198 further includes a motor chamber 216 defined therein, a dirty air inlet 218 defined by the suction nozzle end 180 at the front 212 of the housing 198, a handle 176 located at the rear 214 of the housing 198, a clean air outlet 222 defined therein, and an air flow path (or second air flow path) 196 fluidly connecting the dirty air inlet 218 with the clean air outlet 222.

As shown in fig. 11, motor 194 is disposed in motor chamber 216 and defines a motor axis A4. A filter access door 200 is removably coupled to housing 198 and cooperates with housing 198 to define a filter chamber 224 (best shown in fig. 10). The filter 202 is disposed in the filter chamber 224 and defines a filter axis A5. The dirt cup 204 is movably coupled to the housing 198 and defines a dirt cup axis A6 that extends from a front 226 of the dirt cup 204 to a rear 228 of the dirt cup 204. The motor axis A4, the filter axis A5 and the dirt cup axis A6 extend parallel to one another and generally along the longitudinal axis A3 of the elongate structural member 178. In some embodiments, the motor axis A4 and the filter axis A5 extend coaxially. In the illustrated embodiment, the shroud 206 includes a longitudinal axis A7 that extends parallel to the dirt cup axis A6.

As shown in fig. 10, the filter access door 200 is positioned below the filter axis A5 such that when the filter access door 200 is disassembled, the filter 202 is removable from the filter chamber 224 in a downward direction. In the illustrated embodiment, the filter access door 200 includes a latch 230 having a user actuation portion 232. User actuation of the user actuation portion 232 causes the latch 230 to retract. In the illustrated embodiment, the latch 230 translates upon actuation of the user actuation portion 232. The filter access door 200 may further include a spring or another biasing member to bias the latch toward the extended position. The filter access door 200 further includes a catch 234 positioned opposite the latch 230.

In the illustrated embodiment, the filter 202 is a cylindrical filter in which air enters the filter radially from the outer peripheral surface, along a filter axis A5, and into a central filter air path (fig. 11). The central filter air path is provided in fluid communication with the motor chamber 216 through a filter chamber outlet (fig. 10). The cylindrical filter 202 may be a pleated or non-pleated filter and may be a nonwoven media, foam media, or other filter media, and may include a combination of two or more layers in some embodiments. In some embodiments, filter 202 is a planar filter disposed in air flow path 196 in filter chamber 224 transverse to motor axis A4.

As shown in fig. 10, the housing 198 also includes a filter access opening 236 that is exposed when the filter access door 200 is removed. Housing 198 also includes a first ledge 238 adjacent to filter access opening 236 and a second ledge 240 adjacent to filter access opening 236 on a side of filter access opening 236 opposite first ledge 238. The catch 234 engages a first ledge 238 of the housing 198. The latch 230 engages a second ledge 240 of the housing 198. To disassemble the filter access door 200, the user retracts the latch 230 and swings the filter access door 200 around at least a portion of the catch 234. As such, the latch 230 travels along the arc R1.

In the illustrated embodiment, the filter access door 200 further includes at least one door filter support 242. Housing 198 also includes at least one corresponding housing filter support 244. When the filter access door 200 is coupled to the housing 198, the door filter support 242 and the housing filter support 244 are located in the filter chamber 224. One or both of the door filter support 242 and the housing filter support 244 are provided to orient the filter 202 and may be configured to hold the filter 202 in place within the filter chamber 224. In the illustrated embodiment, when the filter 202 is in place, the filter 202 is directly upstream of the motor 194 (and corresponding fan/impeller).

Fig. 11 also shows the second air flow path 196 entering the dirty air inlet 218, which in some embodiments is located in the suction nozzle end 180, travels through the elongated structural member 178 in a direction generally parallel to the longitudinal axis A3 of the elongated structural member, turns and enters the dirt collection chamber 260 of the dirt cup 204 through the dirt cup inlet 256, exits the dirt cup 204 through the dirt cup outlet 258 (fig. 12), enters the filter chamber 224, passes through the filter 202, enters the motor chamber 216, and exits the clean air outlet 222 (fig. 9 and 10) defined in the housing 198, through the mesh screen 278 (fig. 12) of the shroud 206.

As shown in fig. 2 and 10, the housing 198 further includes a second battery mount (or battery mount) 190. In the illustrated embodiment, the battery holder 190 is disposed below the motor 194. At least a portion of the battery holder 190 is also located on the opposite side of the filter access door 200 from the filter 202. In an alternative embodiment, the battery holder 190 is located on a top 208 that is disposed above the motor 194. In other words, in some embodiments, at least a portion of the battery holder 190 is not located on the opposite side of the filter access door 200 from the filter 202.

The battery holder 190 includes an open end 246, a closed end 248 opposite the open end 246, and at least one battery connection terminal (second battery connection terminal) 192. At least one cell connection terminal 192 is positioned closer to the closed end 248 than the open end 246. In the illustrated embodiment, the battery holder 190 further includes a first rail 250 and a second rail 252 that extend generally parallel to each other. A first rail 250 and a second rail 252 extend between the open end 246 and the closed end 248. The rails 250, 252 are for slidably guiding the battery 106 into engagement with the at least one battery connection terminal 192. The arrangement of the rails 250, 252 forms a concave surface 254 of the battery holder 190 disposed therebetween.

As shown in fig. 2 and 11, at least a portion of the filter access door 200 is adjacent to the battery holder 190. In the illustrated embodiment, at least a portion of the filter access door 200 is substantially flush with the concave surface 254 of the battery holder 190. The filter access door 200 is shown as a stepped door, but may be a substantially planar or other desired shaped panel. In the illustrated embodiment, the portion of the filter access door 200 that is substantially flush with the recessed surface 254 is also located near the open end 246 of the battery holder 190. Specifically, in some embodiments, the user actuated portion 232 of the latch 230 is positioned adjacent the open end 246 of the battery holder 190 and extends toward the closed end 248 of the battery holder 190. In this arrangement, the latch 230 is disposed closer to the battery holder 190 than the catch 234. At least a portion of the first rail 250 is disposed on an opposite side of the user actuation portion 232 from at least a portion of the second rail 252. In other words, the user actuation portion 232 may be at least partially disposed between the first rail 250 and the second rail 252. As such, the arc R1 along which the latch 230 travels upon installation or removal of the filter access door 200 is at least partially surrounded by the battery holder 190. In other words, when the battery 106 is received within the battery holder 190, the installation or removal of the filter access door 200 is blocked by the battery 106.

The battery 106 is detachably coupled to the battery holder 190 of the housing 198. In the illustrated embodiment, when the battery 106 is coupled to the battery holder 190, the battery 106 at least partially covers the filter access door 200. In other words, when the battery 106 is received within the battery holder 190, the battery 106 may cover at least a portion of the filter access door 200. In the illustrated embodiment, the user actuation portion 232 of the latch 230 is covered by the battery 106 when the battery 106 is coupled to the battery holder 190. In some embodiments, the battery 106 covers at least a portion of the user actuation portion 232 of the latch 230, thereby inhibiting access to the user actuation portion 232 when the battery 106 is received within the battery holder 190. To remove the filter 202 from the illustrated filter chamber 224, the user must first remove the battery 106 from the battery holder 190. Once the battery 106 is removed, a user may access and remove the filter access door 200 from the housing 198. The user can remove the filter 202 from the filter chamber 224 only once the filter access door 200 is removed.

As shown in fig. 10, the handheld accessory 104 includes a dirt cup 204 that is movably coupled to the housing 198. In the illustrated embodiment, the dirt cup 204 is detachably coupled to the housing 198, but other embodiments include the dirt cup 204 being pivotably or translatably coupled to the housing 198 without being detachable from the housing 198.

Referring to FIG. 12, the dirt cup 204 includes a dirt cup inlet 256, a dirt cup outlet (or dirt cup opening or dirt cup discharge opening) 258, and a dirt collection chamber 260 at least partially defined between the dirt cup inlet 256 and the dirt cup outlet 258. As shown in fig. 11, the dirt cup outlet 258 is positioned adjacent to and facing the filter chamber 224. Returning to FIG. 12, while the dirt cup 204 may be cylindrical or other shape, the illustrated embodiment includes a dirt cup 204 having a plurality of dirt cup sidewalls 262.

As shown in FIG. 13, the handheld accessory 104 further includes at least one wiping member 264 disposed about the dirt cup opening 258. The wiping member 264 extends inwardly to reduce the size of the dirt cup opening 258 such that the wiping member 264 extends adjacent to or in contact with the sides of the shield 206 when the shield 206 is detached from the dirt cup opening 258, thereby inhibiting debris from being removed with the shield 206. The wiping member 264 is flexible with respect to the dirt cup 204, such as an elastomeric wiper or bristle array. In the illustrated embodiment, the wiping member 264 is a polymer that is overmolded onto the dirt cup 204. Although the dirt cup opening 258 may be circular, oval, or other shape, the illustrated embodiment includes a dirt cup opening 258 having a plurality of open sides 266. In this embodiment, the wiping member 264 is disposed on less than all of the plurality of open sides 266. Specifically, the wiping member 264 is a continuous body disposed on all but one of the plurality of open sides 266, as described further below.

Referring to fig. 12, the handheld accessory 104 further includes a shroud 206. The shield 206 includes a first end 268 and a second end 270 opposite the first end 268. The second end 270 is spaced farther from the dirt cup outlet 258 than the first end 268. Although the shroud 206 may be cylindrical or other shape, the illustrated embodiment includes a shroud 206 having a plurality of shroud sides 272 extending between the first end 268 and the second end 270 of the shroud 206. Specifically, the shroud 206 is shown as a generally hexagonal prism. Other embodiments may include a shroud 206 that is, for example, a generally rectangular prism or cylinder. While the second end 270 of the shield 206 may be rounded or pointed, the illustrated embodiment includes a shield 206 having shield end facets at the second end 270.

The shield 206 further includes a shield frame 276 that supports a mesh screen 278 coupled thereto. As shown in fig. 14, the shield frame 276 and the mesh 278 cooperate to give the shield 206 a shape and define a lateral outer periphery of the shield 206. In the illustrated embodiment, at least one shroud side 272 is at least partially closed to the passing air flow, while the other shroud side 272 is permeable to the passing air flow, thereby forming an air path from the interior of the dirt cup 204 into the shroud 206. The mesh 278 allows the shroud 206 to at least partially filter debris from the air flow passing from the dirt cup inlet 256 to the dirt cup outlet 258. Thus, particulates that may clog or damage the filter 202 are prevented from reaching the filter 202. The mesh screen 278 is selected to have a desired mesh size for operation with the selected filter 202. In some embodiments, the mesh size is between about 100 microns and 1mm, more particularly between about 200 microns and 500 microns. The mesh 278 may be a woven or nonwoven media, a wire mesh, a perforated media, an etched media, or other desired mesh media.

Referring to fig. 12, shroud side 272, which is at least partially closed to the passing air stream, is shown as being completely closed to the passing air stream. Specifically, the shroud 206 includes shroud side sidewalls 280 that form an entirety of one of the shroud sides 272. The shroud side walls 280 block the flow of air through the shroud side 272 such that the shroud side 272 is completely closed to the flow of air passing therethrough. Other embodiments include the shroud side wall 280 blocking only a portion of the shroud side 272. In yet another embodiment, all of the shroud sides 272 are permeable to the flow of air therethrough, such as including a mesh screen 278 on at least a portion of each side 272, forming an air path from the interior of the dirt cup 204 to the shroud 206. In the illustrated embodiment, the shroud lateral side walls 280 are integrally formed as a unitary piece with the shroud frame 276.

In the illustrated embodiment, the second end 270 is closed to the flow of air therethrough. In some embodiments, the second end 270 includes a shroud end wall 282 that blocks air flow through at least a portion of the second end 270. In the illustrated embodiment, the shroud end wall 282 blocks air flow through the entire second end 270. The shroud end wall 282 is integrally formed as a unitary piece with the shroud frame 276. In other embodiments, the second end 270 is permeable to the flow of air therethrough, such as including a mesh screen 278 on at least a portion of the second end 270.

In the illustrated embodiment, the shroud 206 is coupled to the dirt cup 204 and extends at least partially through the dirt cup opening 258 and into the dirt collection chamber 260. As such, at least a portion of the shroud 206 is disposed between the dirt cup inlet 256 and the dirt cup outlet 258 such that the mesh 278 is disposed in the air path between the dirt cup inlet 256 and the dirt cup outlet 258.

The shroud 206 may include a pull tab 284 or other handle so that the shroud 206 may be more easily removed from the dirt cup 204. In the illustrated embodiment, the tabs 284 are integrally formed as a unitary piece with the shroud frame 276. This pull tab 284 is disposed on a first end 268 of the shroud 206, which may be considered an open shroud attachment end.

As shown in FIG. 11, the shield 206 is positioned closer to one dirt cup sidewall 262 than the other dirt cup sidewall 262 such that the shield 206 is off-centered in cross-section with respect to the dirt cup 204. In the illustrated embodiment, the shroud lateral side wall 280 seals off the air flow, thereby preventing debris from collecting in the reduced space between the shroud 206 and the dirt cup side wall 262 adjacent the shroud lateral side wall 280. In some embodiments, at least one of the shroud sides 272 having at least a portion closed to the passing air flow is blocked by its proximity to the nearest dirt cup sidewall 262. In other words, the shroud side 272 is at least partially blocked by the respective dirt cup sidewall 262 such that air flow cannot pass through at least a portion of the respective shroud side 272. In some embodiments, the respective shroud side 272 of the shroud 206 is detachably coupled to the respective dirt cup sidewall 262.

Referring to fig. 12 and 13, the wiping member 264 of the dirt cup 204 wipes the shield 206 when the shield 206 is detached from the dirt cup 204. In some cases, the wiping member 264 wipes the debris/dirt from the shroud 206 and retains the debris/dirt in the dirt collection chamber 260 after the shroud 206 is disassembled. In the illustrated embodiment, the wiping member 264 is disposed on all of the plurality of open sides 266 of the dirt cup opening 258 except for the open side 266 corresponding to the shroud side sidewall 280. In this way, the wiping member 264 does not unnecessarily wear due to wiping the shroud side 272 that does not need to be wiped. In some embodiments, all of the shroud sides 272 are breathable, and the wiping member 264 extends around all of the respective open sides 266.

As shown in fig. 14, the shroud frame 276 is integrally formed as a unitary piece with the shroud lateral side wall 280 in the illustrated embodiment, blocking air flow in cross-section through at least twenty-five percent (25%) of the continuous section of the lateral outer periphery of the shroud 206. In some embodiments, this continuous section is greater than twenty-five percent (25%) and less than fifty percent (50%). In some embodiments, the continuous section of the air flow blocked with the shroud lateral side wall 280 is greater than 5% and less than 25% of the lateral outer perimeter of the shroud 206 in cross-section. The cross-section in fig. 14 is taken through a plane perpendicular to the longest dimension of the shroud 206. In other words, the cross-section in fig. 14 is taken through a plane perpendicular to the longitudinal axis A7 of the shield 206.

Although the present disclosure has been discussed with respect to an upright vacuum cleaner 102 and a handheld accessory 104 in the form of a handheld vacuum cleaner, the present disclosure contemplates combinations of other components. For example, the upright cleaner 102 may be a floor cleaner that includes a cleaning solution tank, a fluid dispensing nozzle, and a scrubbing member for carpet cleaning and the like. The handheld accessory 104 may be a handheld fluid dispensing device including a dispensing nozzle for spraying cleaning liquid for in situ cleaning and the like. The handheld accessory 104 may be a handheld power upholstery or stair cleaning tool, including a motor-driven agitator or brush, or other power cleaning tool.

Referring to fig. 15, another embodiment of a handheld accessory 1104 is shown. Handheld accessory 1104 is similar in many respects to handheld accessory 104 shown in fig. 10. As such, only the differences between handheld accessories 104, 1104 will be discussed herein with respect to handheld accessory 1104 shown in fig. 15. Like features between handheld accessory 104, 1104 are numbered identically, with only a value of 1,000 added to handheld accessory 1104 shown in fig. 15.

Handheld accessory 1104 includes a filter access door 1200 that can be detached to access filter 1202. Filter access door 1200 includes a user actuation portion 1232 that actuates two opposing latches 1230. In the illustrated embodiment, the latch 1230 extends laterally outward in the opposite direction. Actuation of the user actuation portion 1232 retracts the latch 1230 along the length of the filter access door 1200. A spring or other biasing member may resist retraction of the latch 1230. Filter access door 1200 further includes a latch 1234 positioned generally opposite user actuation portion 1232. In the illustrated embodiment, the latch 1234 extends outwardly in a direction perpendicular to a plane containing the laterally outward direction in which the latch 1230 extends.

Fig. 15 also shows that the housing 1198 includes a filter access opening 1236 that is exposed when the filter access door 1200 is removed. Housing 1198 includes a ledge 1238 adjacent to filter access opening 1236. The housing 1198 also includes two opposing passageways 1500 defined therein, generally opposite the ledge 1238.

Referring to fig. 16-18, the filter access door 1200 is shown removed from the housing 1198. When the filter access door 1200 is positioned on the housing 1198, the catches 1234 engage the ledge 1238 and each latch 1230 engages a respective aisle 1500. The user withdraws the latch 1230 to remove the filter access door 1200 by actuation of the user actuation portion 1232 (fig. 16). The user may then swing open filter access door 1200 by pivoting filter access door 1200 about the contact interface between latch 1234 of filter access door 1200 and ledge 1238 of housing 1198 (fig. 17). This pivoting causes each latch 1230 to travel along arc R2 (shown in FIG. 21). Once filter access door 1200 has been swung open a sufficient distance, a user may completely remove filter access door 1200 (FIG. 18) by pulling latch 1234 of filter access door 1200 out of engagement with ledge 1238 of housing 1198.

As shown in fig. 19, after removal of filter access door 1200, the user may then remove filter 1202 from filter chamber 1224. In the illustrated embodiment, filter 1202 includes a handle 1502 for a user to grasp to more easily detach filter 1202 from filter chamber 1224. In some embodiments, the handle 1502 is pivotable relative to the body of the filter 1202 to more easily store the handle 1502 in the filter chamber 1224. The handle 1502 pivots from the storage position (fig. 18) to the deployed position (fig. 19). In some embodiments, the handle 1502 may be biased to one of a storage position and a deployed position.

Referring to fig. 19 and 20, filter 1202 further includes an inclined surface 1504 having a block-receiving recess 1506 defined therein. Handheld accessory 1104 further includes a corresponding block or rail 1508 that extends into filter chamber 1224 and is received in block-receiving recess 1506 to help hold filter 1202 in place in filter chamber 1224. In the illustrated embodiment, the sloped surface 1504 of the filter 1202 at least partially surrounds the block 1508. This interface between the block 1508 and the block-receiving recess 1506 positions the filter 1202 at least one of laterally and rotationally relative to the housing 1198. Some embodiments further include a filter access door 1200 having one or more door filter supports 1242 and/or a housing 1198 having one or more housing filter supports 1244.

As shown in fig. 21 and 22, block 1508 is shown as a single unitary piece with an elongate structural member 1178. In such embodiments, block 1508 may be less susceptible to damage due to incorrect installation or removal of filter 1202. In some embodiments, elongate structural member 1178 is made of a more durable material than other components of handheld accessory 1104. The elongate structural member 1178 is made of metal or rigid nylon, while the housing 1198 is made of a less rigid plastic. Other material selections are also contemplated herein.

As shown in fig. 22, the housing 1198 may be made of multiple separate pieces. These components of the housing 1198 surround and are fastened to the elongated structural member 1178 to form a box beam shape. In the illustrated embodiment, two side panel sections 1510 surround the tang portion 1178B, and at least some of the body portion 1178A of the elongate structural member 1178. Fasteners 1512 couple side panel sections 1510 of housing 1198 to elongate structural member 1178. The fastener 1512 extends in a direction perpendicular to a plane containing the longitudinal axis A3 of the elongate structural member 1178, the dirt cup axis A6, and the tang portion 1178B to increase the rigidity of the handheld accessory 1104. In the illustrated embodiment, the housing 1198 further includes a longitudinal section 1514. As discussed above, the fastener 1513 also couples the longitudinal section 1514 of the housing 1198 to the elongate structural member 1178. Again, the fastener 1513 extends in a direction perpendicular to a plane containing the longitudinal axis A3 of the elongate structural member 1178, but in this case is a different plane.

Referring to fig. 23-25, dirt cup 1204 of handheld accessory 1104 has no wiping member. The shroud 1206 includes a sealing member 1516 around the outer periphery of the shroud 1206 for sealing engagement with the dirt cup 1204. The shroud 1206 further includes a shroud end wall 1282 that is coupled to the shroud collar 1518 by a plurality of shroud ribs 1520. In the illustrated embodiment, the shroud end wall 1282, shroud collar 1518, and shroud rib 1520 are formed together as one unitary piece to form the shroud frame 1276. The shield 1206 further includes two laterally opposite handles 1522 for engagement by a user to pull the shield 1206 out of the dirt cup 1204. In the illustrated embodiment, the handle 1522 is formed as a unitary piece with the remainder of the shroud frame 1276. The dirt cup 1204 also includes a handle recess 1524 to receive the handle 1522 of the shroud 1206.

Various features and advantages of the disclosure are set forth in the following claims.

Claims (25)

1. A vacuum cleaner assembly, comprising:

upright vacuum cleaner comprising

The cleaning head is provided with a cleaning head,

an upright frame pivotally connected to the cleaning head

A first battery mount connected to at least one of the upright frame or the cleaning head;

A handheld accessory detachably coupled to the upright frame, the handheld accessory including a second battery mount; and

a battery configured to be detachably coupled to the first battery mount to power the upright vacuum cleaner and to be detachably coupled to the second battery mount to power the handheld accessory.

2. The vacuum cleaner assembly of claim 1, wherein,

the upright vacuum cleaner includes a first motor,

the hand-held accessory includes a second motor,

in the case where the battery is coupled to the first battery holder, the first motor is powered by the battery and the second motor does not receive electric power, and

in the case where the battery is coupled to the second battery mount, the second motor is powered by the battery and the first motor does not receive electrical power.

3. The vacuum cleaner assembly of claim 2, wherein,

the hand-held accessory includes a handle, and

when the handheld accessory is coupled to the upright frame, the handle acts as a handle for both the handheld accessory and the upright vacuum cleaner.

4. The vacuum cleaner assembly of claim 1, wherein,

the hand-held accessory includes a hand-held vacuum cleaner.

5. The vacuum cleaner assembly of claim 4, wherein,

the hand-held vacuum cleaner includes a suction nozzle, and

with the hand-held vacuum cleaner coupled to the upright frame, the suction nozzle is substantially blocked.

6. The vacuum cleaner assembly of claim 4, wherein,

the upright vacuum cleaner includes a dirt cup and a flow passage through the cleaning head and in fluid communication with the dirt cup, an

The flow channel of the upright vacuum cleaner is isolated from the hand-held vacuum cleaner.

7. The vacuum cleaner assembly of claim 4, wherein,

the hand-held vacuum cleaner includes a handle, and

when the hand-held vacuum cleaner is coupled to the upright frame, the handle acts as a handle for both the hand-held vacuum cleaner and the upright vacuum cleaner.

8. The vacuum cleaner assembly of claim 4, wherein,

the hand-held vacuum cleaner includes an elongated structural member having a nozzle end and a handle opposite the nozzle end, and

the nozzle end of the elongated structural member is detachably coupled to the upright frame.

9. The vacuum cleaner assembly of claim 8, wherein,

In the case of the hand-held vacuum cleaner being coupled to the upright frame, the handle extends from the elongate structural member at an angle relative to the longitudinal axis of the upright frame.

10. The vacuum cleaner assembly of claim 8, wherein,

the handle is a pistol grip handle.

11. The vacuum cleaner assembly of claim 8, wherein,

the upright frame includes a front surface and a rear surface opposite the front surface, and

the elongate structural member is detachably coupled to the upright frame at a location closer to the front surface than the rear surface.

12. The vacuum cleaner assembly of claim 11, wherein,

the elongate structural member further includes an outer surface, and

with the elongate structural member coupled to the upright frame, at least a portion of an outer surface of the elongate structural member is substantially aligned with a front surface of the upright frame.

13. The vacuum cleaner assembly of claim 4, wherein,

the upright frame of the upright vacuum cleaner includes a pivot end and a hand-held end opposite the pivot end,

the cleaning head is pivotally connected to the upright frame proximate the pivot end,

the hand-held vacuum cleaner is detachably coupled to the upright frame at a position closer to the hand-held end than the pivot end, and

With the hand-held vacuum cleaner coupled to the upright frame, the hand-held vacuum cleaner protrudes beyond the hand-held end of the upright frame in a direction away from the pivot end of the upright frame.

14. The vacuum cleaner assembly of claim 13, wherein,

the upright frame includes a longitudinal axis extending through the pivot end and the hand-held end, and

the hand-held vacuum cleaner protrudes beyond the hand-held end of the upright frame in a direction along the longitudinal axis.

15. The vacuum cleaner assembly of claim 14, wherein,

the battery is slidably received on the first battery mount in a direction extending along a longitudinal axis of the upright frame.

16. The vacuum cleaner assembly of claim 15, wherein,

the battery is slidably received on the first battery holder in a direction parallel to the longitudinal axis of the upright frame.

17. The vacuum cleaner assembly of claim 1, wherein,

the first battery holder and the second battery holder are identical.

18. A vacuum cleaner assembly, comprising:

an upright vacuum cleaner including a first battery holder;

a handheld accessory detachably coupled to the upright vacuum cleaner, the handheld accessory including a second battery mount;

A battery configured to be detachably coupled to the first battery mount and to the second battery mount; and is also provided with

Wherein, the liquid crystal display device comprises a liquid crystal display device,

when the battery is coupled to the first battery holder, the battery only powers the upright vacuum cleaner, and

when the battery is coupled to the second battery mount, the battery only powers the handheld accessory.

19. The vacuum cleaner assembly of claim 18, wherein,

the hand-held accessory further includes a handle, and

the handle acts as a handle for operating the upright vacuum cleaner when the hand-held accessory is coupled to the upright frame.

20. The vacuum cleaner assembly of claim 18, wherein,

only the hand-held accessory includes a handle.

21. The vacuum cleaner assembly of claim 18, wherein,

the upright vacuum cleaner further includes a first air flow path,

the hand-held accessory further includes a second air flow path, and

the first air flow path and the second air flow path are separated from each other.

22. A vacuum cleaner assembly, comprising:

an upright vacuum cleaner, the upright vacuum cleaner comprising

A first motor, and

a first battery connection terminal configured to electrically couple the first motor to a battery;

a hand-held accessory detachably coupled to the upright vacuum cleaner, the hand-held accessory comprising

A second motor, and

a second battery connection terminal configured to electrically couple the second motor to a battery.

23. The vacuum cleaner assembly of claim 22, wherein,

the upright vacuum cleaner further includes a first battery holder having the first battery connection terminal,

the hand-held accessory further includes a second battery mount having the second battery connection terminal, and

the first battery holder and the second battery holder are configured to interchangeably removably couple to a battery having a corresponding holder structure.

24. The vacuum cleaner assembly of claim 23, wherein,

the first battery holder and the second battery holder are configured to receive one of the battery and the second battery.

25. The vacuum cleaner assembly of claim 24, wherein,

the battery has a different characteristic than the second battery, the characteristic selected from the group consisting of battery capacity, voltage, current, resistance, and cell count.

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