riken seiki hydraulic pump pricelist

The global Hydraulic Pumps market size is projected to reach multi million by 2028, in comparision to 2021, at unexpected CAGR during 2022-2028 (Ask for Sample Report).

Before creating an associate degree investment, doing business analysis, or providing consulting services in an exceedingly Hydraulic Pumps market, it"s crucial to grasp however sensitive the business is to external threats and to remember any gift problems. These very important professions gain from the marketing research on Hydraulic Pumps. The market is more split exploitation words like Hydraulic Gear Pumps,Hydraulic Vane Pumps,Hydraulic Piston Pumps,Others and supported applications like Mobility,Machine Tool,Industrial Machine,Beverage Dispenser,Others into divisions per application. Regional segmentation of the market and trends includes North America: United States, Canada, Europe: GermanyFrance, U.K., Italy, Russia,Asia-Pacific: China, Japan, South, India, Australia, China, Indonesia, Thailand, Malaysia, Latin America:Mexico, Brazil, Argentina, Colombia, Middle East & Africa:Turkey, Saudi, Arabia, UAE, Korea together of many subgroups. within the study report, the foremost markets are examined together with Kawasaki,Bosch Rexroth,KYB,Eaton,Parker Hannifin,Sumitomo Precision,Nachi-Fujikoshi,Doosan Mottrol,Hydac International,Daikin,Avic Liyuan Hydraulic,Yuken,Danfoss,Takako,Linde Hydraulics,Casappa,Hawe Hydraulik,Oilgear,Tokyo Keiki,Yantai Eddie Precision,Huade,Jiangsu Hengyuan Hydraulic,Riken Seiki,Zhejiang XianDing,Veljan Hydrair.

Businesses might find prospective customers and have a solid understanding of the business for the Hydraulic Pumps market. It"s easier to forecast a company"s future mechanical phenomenon once you are aware of the factors that have an effect on business growth. So as to predict how the business can perform, the analysis provides forecasts for key components.

Sections in Hydraulic Pumps Market Report:Section 1in the main provides a summary of the Hydraulic Pumps market with a spotlight on the key trends and market definitions and developments.

The Hydraulic Pumps Market business analysis Report contains:Every aspect of the Hydraulic Pumps market is roofed in nice detail in every project report, from marketing research to acceptance of availableness for a range of wants, together with plant and machinery, raw materials, and money projections.

Making system dismantling easier promotes system improvement. The Hydraulic Pumps company conducts analysis on vital trends that have an effect on a company"s success and aids in guiding choices supported by vital recent events.

The COVID-19 virus natural event inevitably had an impact on the marketplace for Hydraulic Pumps. The pandemic-related issues created the Hydraulic Pumps market to move quickly and hazardously. The confusing and sophisticated surroundings of COVID-19 needed a special approach to crisis management than ancient strategies and groups may offer. If businesses take the proper lessons from the eruption and strengthen their resilience to ensuing catastrophe, they"ll gain from the COVID-19 disruption.

The challenges that up-to-date marketers encounter are examined during this marketing research study on Hydraulic Pumps. The exaggerated level of the market fight is the primary downside. This report offers answers to those problems in addition to an intensive analysis of the business.

Reasons to get the Hydraulic Pumps Market Report:The analysis study"s summary of the Hydraulic Pumps market and details on its segmentation and classification facilitates the corporate to comprehend the market higher.

The primary issue influencing market growth, current market trends, and also the sector"s restrictive framework is the most foci of the market study provided by the Hydraulic Pumps marketing research.

High Pressure air operated hydraulic pumping systems are complete, self-contained units and ready to operate. Just hook up standard shop air supply (maximum 100 psi) to connection supplied on the side of the console. Discharge capacities range to 64 in3/min.

System includes hydraulic oil reservoir, oil filter, air operated hydraulic pump, pressure gauge, panel mounted high pressure valves, safety head assembly, panel mounted air regulator and gauge and air line filter and lubricator. All components are enclosed in a steel console with only the back exposed. Dimensions of standard systems are 26" wide, 24" deep and 40" high.

Riken Seiki Type P-1B Hydraulic Hand Pump 70 MPA, 700 Bar. Nothing to test this on, but we pumped it with the valve open and shot oil across the room.No handle- priced accordingly.

The Asia-Pacific Hydraulic Pumps market is valued at US$ 3562.20 million in 2020. The market size will reach US$ 4946.97 million by the end of 2027, growing at a CAGR of 4.80% during 2020-2027.

Hydraulic Pumps market is segmented by Type, and by Application. Players, stakeholders, and other participants in the Asia-Pacific Hydraulic Pumps market will be able to gain the upper hand as they use the report as a powerful resource. The segmental analysis focuses on sales, revenue and forecast by Type, and by Application for the period 2016-2027.

The present invention relates to a clamp system which employs a plurality hydraulic clamps to removably secure a workpiece to a base plate. More specifically, the present invention relates to a main cylinder unit in each hydraulic clamp supplied through wall-based hydraulic pathways.

Referring now to FIG. 12, standard clamp system includes a plurality of clamp devices 210 to secure a workpiece Wa to a base plate 200. During operation, clamp devices 210 operate through hydraulic pressure to engage and disengage workpiece Wa. During normal engagement, workpiece Wa solidly engages base plate 200 for machining.

A guide 215 forms a rod-side cylinder end wall on main cylinder unit 211 and guides piston rod 213 during operation. A hydraulic pipe 216 joins a hydraulic hose (not shown) to main cylinder unit 211.

During operation, hydraulic pipe 216 supplies hydraulic pressure from the hydraulic pressure supply device (not shown) to main cylinder unit 211. As hydraulic pressure in main cylinder unit 211 increases, piston rod 213 lowers. As piston rod 213 lowers, arm 214 presses a clamping point (not shown) on workpiece Wa onto a receiving base 202 and base plate 200.

Clamping devices 210 operate as horizontally pivoting clamps which allow arms 214 to pivot in a tandem with operation of piston rods 213 to allow easy placement of workpiece Wa. Unfortunately, clamping devices of this design have several undesirable features. First, hydraulic pipe 216 is easily damaged causing undesirably downtime and loss in production efficiency. Second, guide members 215 require a larger base plate 200 and reduce machining efficiency. Third, where hydraulic pipes 216 are damaged, clamping force may be unexpectedly reduced causing operator injury. Fourth, since each clamping device 210 requires an individual hydraulic pipe 216 complexity and costs are increased.

A horizontal oil path 232 and a vertical oil path 231 link a hydraulic port 232 to a hydraulic pressure supply device (not shown). Horizontal oil path 232 and vertical oil path 231 are inside base plate 230. Base plate 230 operates to protect horizontal and vertical oil paths 232, 231. Unfortunately, it is difficult to produce secure, clean, and effective internal oil passageways, thereby increasing manufacturing costs and reducing reliability.

Spacer 225 includes an oil path 226. Oil path 226 joins hydraulic port 223 of main cylinder unit 221 to a hydraulic port 227. Hydraulic port 227 is on a bottom end of oil path 226 and spacer 225. A hydraulic pipe 236 extends from the hydraulic pressure supply device (not shown) to base plate 235. A connected oil path 237 extends continuously from hydraulic pipe 236 to hydraulic port 223. Connected oil path 237 supplies hydraulic pressure from the hydraulic pressure supply device to main cylinder unit 221.

Referring additionally to FIG. 15, a fourth clamp system includes a pair of spacers 225 separating main cylinder unit 221 from a base plate 240. Oil paths 226 in spacers 225 are aligned with a vertical oil path 241. Oil path 241 and a horizontal oil path 242 transport hydraulic pressure from the hydraulic pressure supply device through oil paths 226 to main cylinder unit 221.

In each clamp system described above, single or multiple spacers 218,225 adjust the height at which arms 214 of main cylinder units 220 clamp workpieces Wa. Unfortunately, each change in workpiece Wa size, requires disassembly, alignment of the multiple oil pathways, and secure reassembly. Such disassembly-alignment-reassembly actions increase production time, risk equipment damage, and increase the probability of hydraulic leaks.

Referring to FIGS. 16 and 17, a plurality of clamp devices 250 are disposed along an edge of a base plate 260. A pair of hydraulic ports 252, 253 are at a bottom end of a flange 251 on each clamp device 250.

A plurality of clamping oil paths 261 supply hydraulic pressure from an external supply device (not shown) to each hydraulic port 252 on each respective clamp device 250. Clamping oil paths 261 are inside base plate 260.

A plurality of unclamping oil paths supply 265 return hydraulic pressure to the external supply device from each hydraulic port 253 of each respective clamp device 250. Unclamping oil paths 265 are inside base plate 260.

A plurality of perpendicular oil paths 264 connects each oil path 263 to each respective hydraulic port ports 252. A plurality of perpendicular oil paths 267 connects each oil path 267 to each respective hydraulic port 253.

During operation it is desirable for base plate 260 to have both compact dimensions and sufficient strength and rigidity to secure workpieces Wa of a predetermined size. It is also desirable to maximize available work surface on each base plate 260. By maximizing the available work surface and minimizing the dimensions of base plate 260, multiple operations may be performed at a single work station. The more compact base plate 260, the more compact a machining tool (restricted by the mounting zone of the base plate) may be for each workpiece Wa. Unfortunately, multiple hydraulic pipes reduce a base plate to workpiece ration and increase costs.

For each design described above, the plurality of hydraulic pipes restricts movement when transporting each respective base plate and increases production time.

The present invention relates to a clamp system including a plurality of clamping devices arrayed along at least a first hydraulic supply loop and a plurality of support devices arrayed along at least a second hydraulic supply loop. The clamping devices may include vertical rotating clamping devices which rotate vertically to secure a workpiece to a base plate. The clamping devices may also include horizontally rotating clamping devices which rotate axially and extend vertically to clamp the workpiece. The support devices support and stabilize the workpiece during machining operations. The first and second hydraulic supply loops are interconnected and allow the clamping devices to clamp the workpiece before the support pieces support the workpiece. The second hydraulic supply loop boosts support to and locks the support devices for additional stability.

According to an embodiment of the present invention there is provided a clamp system, for disengageably securing a workpiece using a plurality of hydraulic clamp devices, a clamp system wherein: a thick base plate is disposed to allow mounting of said plurality of clamp devices, each of said hydraulic clamp devices including a main cylinder unit disposed in a wall of said base plate and oriented along a thickness axis of said base plate, an output member including a piston rod extending from said main cylinder unit toward a surface of said base plate, a guide member disengageably secured to said surface of said base plate and guiding said piston rod to allow a forward and a back motion, said guide member covering a major portion of said piston rod projecting out from said surface and not obstructing a clamping operation of said output member, a rod-side cylinder end wall of said main cylinder unit disengageably secured to said base plate, and a first oil path formed in said wall of said base plate to supply a hydraulic pressure from a hydraulic pressure supplying means to each said main cylinder unit of said plurality of clamp devices.

According to another embodiment of the present invention there is further provided a clamp system, for securing a workpiece, wherein: said workpiece, clamped by said plurality of clamp devices, is supported from said base plate by a plurality of support devices, each of said support devices including a second main cylinder unit disposed in said wall of said base plate and oriented along a thickness axis of said base plate, a support member including a second piston rod extending from said main cylinder unit toward said surface of said base plate, and a second oil path formed in said wall of base plate to supply said hydraulic pressure from said hydraulic pressure supplying means to said second main cylinder units of said plurality of support devices.

According to another embodiment of the present invention there is further provided a clamp system, for securing a workpiece, wherein: a hydraulic pressure booster means disposed on said base plate is effective to increase said hydraulic pressure received from said hydraulic pressure supplying means and supplying said increased hydraulic pressure to said plurality of support devices via said second oil path.

According to an embodiment of the present invention there is provided a clamp system, for disengageably securing a workpiece to a base plate, comprising: a plurality of clamping members on said base plate; said plurality of clamping members effective to hydraulically and securely clamp said workpiece to said base plate during an external operation; a plurality of support members on said base plate; said plurality of support members effective to hydraulically and securely support said workpiece on said base plate during said external operation; hydraulic pressure means for supplying at least a first hydraulic pressure to said plurality of clamping members and to said plurality of support members to enable respective clamping and supporting of said workpiece; and hydraulic booster means for boosting said at least first hydraulic pressure to a boosted hydraulic pressure, and for supplying said boosted hydraulic pressure to and locking said plurality of support members, whereby said clamping system easily and securely clamps and supports said workpiece and allows speedy removal for later processing.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of clamping members includes at least one vertically pivoting hydraulic clamp device.

According to another embodiment of the present invention there is provided a clamp system, wherein: said hydraulic pressure means includes at least first oil path means for supplying said first hydraulic pressure downstream to said plurality of support members.

According to another embodiment of the present invention there is provided a clamp system, wherein: said hydraulic booster means includes at least second oil path means for suppling said boosted hydraulic pressure downstream to said plurality of said support members; and said hydraulic booster means effective to boost said at least first hydraulic pressure to said boosted hydraulic pressure after said workpiece is securely clamped to said base plate at said first hydraulic pressure, whereby said support members will not shift said workpiece upon application of said boosted hydraulic pressure.

According to another embodiment of the present invention there is provided a clamp system, wherein: said first oil path means for supplying is in said base plate; and said second oil path means for supplying is in said base plate, wherein said base plate provides easy protection for said first oil path means and said second oil path means and minimizes damage to said hydraulic pressure means and said hydraulic booster means during said external operation.

According to another embodiment of the present invention there is provided a clamp system, wherein: said first oil path means for supplying supplies said first hydraulic pressure downstream to said plurality of support members along a series hydraulic circuit.

According to another embodiment of the present invention there is provided a clamp system, wherein: said second oil path means for supplying supplies said boosted hydraulic pressure along a parallel hydraulic circuit.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of clamping members including at least one horizontally pivoting hydraulic clamp device; and said at one vertically pivoting hydraulic clamp device operable in tandem with said at least one horizontally pivoting hydraulic clamp device upon receiving said first hydraulic pressure from said hydraulic pressure means for supplying.

According to another embodiment of the present invention there is provided a clamp system, further comprising: a main cylinder unit in said vertically pivoting hydraulic clamp device; said main cylinder unit extending perpendicular to said base plate; a piston rod in said main cylinder unit; said piston rod extending away from said main cylinder unit when said main cylinder unit receives said first hydraulic pressure in a clamping direction and retracting toward said main cylinder unit when said main cylinder unit receives said first hydraulic pressure in an unclamping direction; a guide member on said main cylinder unit; said guide member disengageably fixed to an upper surface of said base plate; and said guide member effective to support said piston rod during said extending and said retracting whereby said guide member protects said piston rod from damage and debris during said external operation.

According to another embodiment of the present invention there is provided a clamp system, further comprising: a rod-side cylinder end wall on main cylinder unit; said rod-side cylinder end wall integral with guide member; said piston rod on an output member; a pivot arm on said output member; said pivot arm is pivotably supported on a first end of said piston rod; said pivot arm effective to securely clamp said workpiece to said baseplate during said clamping; a pivot linking mechanism rotatively linking said pivot arm and said guide member; a pivot linking member in said pivot linking mechanism; and said pivot linking mechanism vertically pivoting said pivot arm in tandem with said extending and said retracting of said piston rod, whereby said pivot linking mechanism and said pivot arm transmit said first hydraulic force and securely clamp an speedily unclamp said workpiece.

According to another embodiment of the present invention there is provided a clamp system, further comprising: a second main cylinder unit in said horizontally pivoting hydraulic clamp device; said second main cylinder unit extending perpendicular to said base plate; a second piston rod in said second main cylinder unit; said second piston rod extending away from said second main cylinder unit when said second main cylinder unit receives said first hydraulic pressure in said unclamping direction and retracting toward said second main cylinder unit when said second main cylinder unit receives said first hydraulic pressure in said clamping direction; a second guide member on said second main cylinder unit; said second guide member disengageably fixed to an upper surface of said base plate; and said second guide member effective to support said second piston rod during said extending and said retracting whereby said second guide member protects said second piston rod from damage and debris during said external operation.

According to another embodiment of the present invention there is provided a clamp system, further comprising: a second rod-side cylinder end wall on second main cylinder unit; said second rod-side cylinder end wall integral with second guide member; said second piston rod on a second output member; a second pivot arm on said second output member; said second pivot arm fixably extending from a first end of said second piston rod perpendicular to said second piston rod; said second pivot arm effective to securely clamp said workpiece to said baseplate during said clamping; a pivoting mechanism rotatably and extendably linking said second piston rod and said second main cylinder unit; and said pivoting mechanism effective to vertically extend, retract, and pivot said second pivot arm in tandem with said extending and said retracting of said second piston rod, whereby said pivoting linking mechanism transmits said first hydraulic force and securely clamp an speedily unclamps said workpiece.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of support members includes at least a first vertical support device; a third main cylinder unit in said first vertical support device; said third main cylinder unit extending perpendicular to said base plate; a cylinder cap in said main cylinder unit; a head-side cylinder end wall secured to said cylinder cap; said cylinder cap and said head-side cylinder end wall securing said third main cylinder unit in said base plate; a support member in said vertical support device; said support member extends perpendicular to said base plate and away from said main cylinder unit; a third piston rod in said support member; a support rod extending from an upper end of said third piston rod; said third main cylinder unit effective to receive said first hydraulic pressure as at least one of a first support pressure and a first unsupporting pressure and respectively extending and retracting said third piston rod according to said first hydraulic pressure; a third guide member extending away from said base plate; said third guide member guidably surrounding and supporting said support member during said extension and said retraction, thereby protecting said support member from debris and damage; and means for receiving said boosted hydraulic pressure from said hydraulic booster means and releasably locking said support member against said workpiece relative to said third main cylinder, whereby said workpiece is supported at a pressure greater than said first hydraulic pressure.

According to another embodiment of the present invention there is provided a clamp system, for disengageably securing a workpiece to a base plate, comprising: a plurality of clamping members on said base plate; said plurality of clamping members effective to hydraulically clamp said workpiece to said base plate; a plurality of support members on said base plate; said plurality of support members effective to hydraulically support said workpiece on said base plate; hydraulic pressure means for supplying at least a first hydraulic pressure to each said clamping member and to each said support member; and hydraulic booster means for boosting said at least first hydraulic pressure to a boosted hydraulic pressure, and for supplying said boosted hydraulic pressure to and locking said plurality of support members, whereby said clamping system easily and securely clamps and supports said workpiece and allows speedy removal for later processing.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of clamping members are vertically pivoting hydraulic clamp devices.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of clamping members are horizontally pivoting hydraulic clamp devices.

According to another embodiment of the present invention there is provided a clamp system, for disengageably securing a workpiece to a base plate, comprising: a plurality of clamping members on said base plate; said plurality of clamping members effective to hydraulically and securely clamp said workpiece to said base plate during an external operation; said plurality of clamping members including at least one vertically pivoting hydraulic clamp device; a plurality of support members on said base plate; said plurality of support members effective to hydraulically and securely support said workpiece on said base plate during said external operation; hydraulic pressure means for supplying at least a first hydraulic pressure to said plurality of clamping members and to said plurality of support members; and hydraulic booster means for boosting said at least first hydraulic pressure to a boosted hydraulic pressure, and for supplying said boosted hydraulic pressure to and locking said plurality of support members, whereby said clamping system easily and securely clamps and supports said workpiece and allows speedy removal for later processing.

According to another embodiment of the present invention, there is provided a clamp system, for disengageably securing a workpiece to a base plate, comprising: a plurality of clamping members on said base plate; said plurality of clamping members effective to hydraulically and securely clamp said workpiece to said base plate during an external operation; said plurality of clamping members including at least one vertically pivoting hydraulic clamp device and at least one horizontally pivoting hydraulic clamp device; a plurality of support members on said base plate; said plurality of support members effective to hydraulically and securely support said workpiece on said base plate during said external operation; hydraulic pressure means for supplying at least a first hydraulic pressure to said plurality of clamping members and to said plurality of support members; and hydraulic booster means for boosting said at least first hydraulic pressure to a boosted hydraulic pressure, and for supplying said boosted hydraulic pressure to and locking said plurality of support members, whereby said clamping system easily and securely clamps and supports said workpiece and allows speedy removal for later processing.

According to another embodiment for the present invention there is provided a clamp system, for disengageably securing a workpiece to a base plate using a plurality of hydraulic clamp devices, comprising: said plurality of hydraulic clamp devices on said base plate; at least a main cylinder unit in each said hydraulic clamp device; said main cylinder unit disposed in a wall of said base plate; said main cylinder unit oriented along a first thickness axis of said base plate; at least an output member in each said hydraulic clamp device; a piston rod in each said output member extending away from said main cylinder unit; a guide member disengageably secured to a surface of said base plate; said guide member effective to guide said piston rod during an extension and a retraction; said guide member covering at least have of said piston rod projecting away from said surface of said base plate; a rod-side cylinder end wall on said main cylinder unit; hydraulic pressure supplying means for supplying at least a first hydraulic pressure to said main cylinder units; said rod-side cylinder mend wall disengageably secured to said base plate; and at least a first oil path in a wall of said base plate effective supply said first hydraulic pressure from hydraulic pressure supplying means to said main cylinder units, whereby said plurality of clamp devices securely clamp said workpiece to said base plate.

According to another embodiment of the present invention there is provided a clamp system, further comprising: a plurality of support devices; said plurality of support devices extending away from said base plate; said plurality of support devices effective to support an external clamped workpiece away from said base plate during an external operation; each said support device including a second main cylinder unit; said second main cylinder unit disposed in said wall of said base plate; said second main cylinder unit oriented along said thickness axis of said base plate; a second support member in each said plurality of support devices; said second support member including a second piston rod; said second piston rod extending from said second main cylinder unit away from said base plate; a second oil path in said base plate; and said second oil path supplying said first hydraulic pressure from said hydraulic pressure supplying means to each said second main cylinder units of said plurality of support devices.

According to another embodiment of the present invention there is provided a clamp system, further comprising: means for boosting said first hydraulic pressure received said hydraulic pressure supplying means to a second hydraulic pressure; said means for boosting on said base plate; said means for boosting increasing including means for supplying said second hydraulic pressure to said plurality of support devices, whereby said plurality of support devices provide increased support to said workpiece.

According to another embodiment of the present invention there is provided a clamp system, wherein: said means for boosting includes at least a second oil path; said second oil path effective to transport said second hydraulic pressure to said plurality of support devices.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of hydraulic clamp devices includes at least one horizontally pivoting hydraulic clamp device; a pivoting mechanism in said horizontally pivoting hydraulic clamp device; and said pivoting mechanism effective to pivot said piston rod an a horizontal clearance arc in tandem with a clamping and an unclamping action of said horizontally pivoting clamp device, whereby said workpiece is speedily clamped to said baseplate.

According to another embodiment of the present invention there is provided a clamp system, wherein: said plurality of hydraulic clamp devices includes at least one vertically pivoting hydraulic clamp device; said vertically pivoting hydraulic clamp device includes at least an output member; said output member includes a pivot arm having a pivotably supported pivot point; a pivot point link member operably joined to said guide member; a pivot point link member supporting said pivot point and said pivot arm; and said pivot point link member and said output ember effective to vertically pivot said output member relative to said base plate in tandem with a clamping and unclamping action of said vertically pivoting hydraulic clamp device, whereby said workpiece is speedily clamped to said baseplate.

According to another embodiment of the present invention there is provided a clamp system, wherein: said at least first oil path includes a first oil path section joining said at least main cylinder units to said hydraulic pressure supplying means; said first oil path section parallel to a surface of said base plate.

According to another embodiment of the present invention there is provided a clamp system, wherein: said at least first oil path includes at least a first clamping path and a first unclamping path; said first clamping path effective to supply said first clamping pressure to each said main cylinder unit during a clamping operation; said first unclamping path effective to release said first clamping pressure from each said main cylinder unit during an unclamping operation, and said first clamping path and said first unclamping path are parallel to each other and separated along an axis perpendicular to a face of said base plate, whereby said plurality of hydraulic clamping devices is easily and simply clamped and unclaimed and said clamping system is simplified to minimize component damage.

The present invention provides a clamp system for disengageably securing a workpiece using a plurality of hydraulic clamp devices. A thick base plate is disposed to allow the plurality of clamp devices to be mounted. Each of the hydraulic clamp devices includes a main cylinder unit disposed in a wall of the base plate and oriented along a thickness axis of the base plate; an output member including a piston rod extending from the main cylinder unit toward a surface of the base plate; a guide member disengageably secured to the surface of the base plate and guiding the piston rod to allow forward and back motion, the guide member covering a major portion of the piston rod projecting out from the base plate surface while not obstructing clamping operations of the output member; a rod-side cylinder end wall of the main cylinder unit disengageably secured to the base plate. A first oil path is formed in the wall of the base plate to supply hydraulic pressure from hydraulic pressure supplying means to the main cylinder units of the plurality of clamp devices.

After opening, the output members of the plurality of clamp devices are put in a standby state and the workpiece is mounted on the base plate. Once the workpiece is mounted on the base plate and aligned to a predetermined position, hydraulic pressure is sent from hydraulic pressure supplying means to the main cylinder units of the plurality of clamp devices via the first oil path formed in the wall of the base plate. This drives the piston rods of the clamp devices, and the workpiece is pressed against and secured to the base plate by the plurality of output members including the piston rods.

In particular, the main cylinder units of the clamp devices are mounted in the wall of the base plate along the thickness axis of the base plate. The first oil paths supplying hydraulic pressure from the hydraulic pressure supply device to the main cylinder units of the plurality of clamp devices are formed inside the wall of the base plate. As a result, the wall of the base plate can be used effectively as a section of the main cylinder unit. Also, the structure of the oil paths supplying hydraulic pressure to the plurality of clamp devices can be simplified, and the design and processing operations can be simplified.

The hydraulic port of the main cylinder unit can be formed in the wall of the base plate parallel to the base plate, and the first oil path can be connected to the main cylinder unit using a simple oil path that is parallel to the base plate. This eliminates the need to form oil paths in the base plate, the main cylinder unit, and the guide member that are oriented along the thickness axis of the guide member. Thus, the structure of the oil paths supplying hydraulic pressure to the plurality of clamp devices can be made simple.

If the clamp devices are to be disposed at the edges of the base plate, there is no need to form the first oil path further out toward the edge than the clamp device. This eliminates the need for the corresponding space. Since there is no need to connect hydraulic pipes to the guide member, the guide member can be made more compact. As a result, the required area (i.e., the planar size) of the base plate can be made as compact as possible and the work area ratio on the upper surface of the base plate can be increased.

A plurality of support devices can be disposed to support the workpiece, which is clamped by the plurality of clamp devices, onto the base plate from behind. In this case, the support devices include: a main cylinder unit disposed inside the wall of the base plate along the thickness axis of the base plate; and a support member including a piston rod extending toward the surface of the base plate from the main cylinder unit. A second oil path is formed in the wall of the base plate to supply hydraulic pressure from hydraulic pressure supplying means to the main cylinder units of the plurality of support devices.

Furthermore, the wall as the base plate can be used effectively as part of the main cylinder unit. Also, the structure of the oil paths supplying hydraulic pressure to the main cylinder units of the plurality of support devices can be simplified.

Furthermore, a hydraulic pressure booster can be disposed on the base plate to increase the hydraulic pressure received from hydraulic pressure supplying means and supplying the pressure to the plurality of support devices via the second oil path. In this case, hydraulic pipes for supplying the hydraulic pressure from the hydraulic pressure booster can be eliminated, thus simplifying the structure and reducing production costs.

The main cylinder unit of the hydraulic pressure booster can also be disposed in the wall of the base plate. In this case, a section of the base plate can be used effectively as a section of the main cylinder unit. This simplifies the structure of the hydraulic pressure booster and allows the base plate to be a structure that can be easily transported. Also, the structure of the oil paths supplying hydraulic pressure to the support device from the hydraulic pressure booster can be simplified.

In the hydraulic clamp device described above, a pivoting mechanism may be disposed on the main cylinder unit so that the piston rod is pivoted back and forth approximately 90 degrees in tandem with the action of the piston rod. In this case, the output member can be pivoted 90 degrees from the clamping position when mounting the workpiece to the base plate or when moving the base plate so that the output member, including the piston rod, does not get in the way.

Also, the hydraulic clamp device can include a pivot arm with an output member pivotably supported at a pivot point. A support link member supporting this pivot point is connected to the guide member. In this case, the pivot arm can be pivoted from the clamp position when mounting the workpiece to the base plate or moving it from the base plate so that the output member does not get in the way of the pivot arm.

In the first oil path described above, the oil path section connected to the main cylinder unit of the hydraulic clamp device can be formed parallel to the surface of the base plate. Thus, a majority of the first oil path including this oil path section can be formed parallel to the surface of the base plate. This simplifies the structure of the first oil path and simplifies design and processing. The plurality of hydraulic clamp devices can be connected in series via the first oil path, and, in this case, the structure of the first oil path can be made even more simple.

Also, in the first oil paths, the oil path sections connecting at least the main cylinder units of the hydraulic clamp devices of the same type can be formed parallel to the surface of the base plate. Since a majority of the first oil path can be formed parallel to the surface, the structure of the first oil path can be simplified and design and processing can be simplified. Furthermore, if the hydraulic clamp device is disposed near the edge of the base plate, the space required for forming the first oil path at the edge of the base plate for the clamp device is not needed, allowing the base plate to be made more compact and allowing the work area ratio to be increased. The plurality of hydraulic clamp devices can be connected in series via the first oil path, and this can further simplify the structure of the first oil path.

A plurality of hydraulic clamp devices 3 are on a first side of base plate 2. A plurality of hydraulic clamp device 4 are on a second side of base plate 2 opposite hydraulic clamp devices 3. During operation, the plurality of hydraulic clamp devices 3, 4 operate to secure workpiece W to base plate 2.

Hydraulic clamp devices 3 are vertically pivotable relative to base plate 2. Hydraulic clamp devices 4 are horizontally pivotable relative to base plate 2. In combination, hydraulic clamp devices 3, 4 are rapidly adaptable to unusually shaped workpieces W.

A plurality of support devices 5, 6, mounted on base plate 2 operate to support workpiece W during operation, as will be described. A hydraulic pressure supply device 7 connects with and supplies hydraulic pressure to clamp devices 3, 4 and plurality of support devices 5, 6, as will be explained. Hydraulic pressure supply device 7 normally supplies an average hydraulic pressure range of 7 MPa. A hydraulic pressure booster 8 links with hydraulic pressure supply device 7. Hydraulic pressure booster 8 operates in conjunction with hydraulic pressure supply device 7 and increases the average pressure supply range to approximately 25 Mpa for support devices 5, 6. During operation, hydraulic pressure applied to workpiece W is adjustable through operation of hydraulic pressure supply device 7 and hydraulic pressure booster 8.

Each hydraulic clamp device 3 includes a main cylinder unit 30. Each hydraulic clamp device 4 includes a main cylinder unit 50. Each support device 5, 6 includes a main cylinder unit 70. The walls of base plate 2 constitute main cylinder units 30, 50, and 70 vertically relative to a thickness axis in positions selected to support workpiece W.

A plurality of clamping oil paths 10 connect hydraulic pressure supply device 7 to each main cylinder unit 30, 50. A plurality of unclamping oil paths 11 connect each main cylinder unit 30, 50 to hydraulic pressure supply device 7. During clamping operations, hydraulic clamping pressure passes through clamping oil paths 10 and clamps main cylinder units 30, 50. During unclamping operations, hydraulic pressure releases through unclamping oil paths 11 and unclamp main units 30, 50. Clamping oil paths 10 and unclamping oil paths 11 are hereinafter collectively referred to as first oil paths 10, 11.

During operation, first oil paths 10, 11 supply hydraulic pressure from hydraulic pressure supply device 7 to each main cylinder unit 30, 50 and enable respective clamp devices 3, 4 to operate. First oil paths 10, 11 are inside base plate 2 parallel to a workpiece W support surface. First oil paths 10, 11 extend along a length of base plate 2 and pass through a center axis of each respective main cylinder unit 30, 50.

A plurality of second oil paths 12, 13 connect hydraulic pressure supply device 7 and hydraulic pressure booster 8 to each main cylinder unit 70, as will be explained. During operation, second oil paths 12, 13 supply hydraulic pressure from hydraulic pressure supply device 7 to each main cylinder unit 70 and enable respective support devices 5, 6 to operate. Second oil paths 12, 13 are inside base plate 2.

Hydraulic pressure booster 8 attaches in a fixed manner to a bottom of base plate 2. A hydraulic pressure discharge port 13 aconnects in a fluid-tight manner to second oil path 13 formed in base plate 2. The position at which hydraulic pressure booster 8 attaches to base plate 2 is not limited to the bottom of base plate 2, but is adaptable according to production needs. For example, hydraulic pressure booster 8 may be attached to the side of base plate 2 or may be outside of base plate 2 altogether.

Referring now to FIG. 3, each hydraulic clamp device 3 includes main cylinder unit 30 and a piston rod 32. During operation, piston rod 32 operates relative to main cylinder unit 30, as will be explained. An output member 31 rotatably extends from piston rod 32. Output member 31 includes a pivot arm 33. A pin 32 apivotably joins pivot arm 32 to main cylinder unit 30.

Main cylinder unit 30 includes a cylinder hole 3 a. Cylinder hole 3 ais formed integrally within base plate 2. Guide member 34 covers an upper end of cylinder hole 3 a. Rod-side cylinder end wall 41 extends into and hydraulically seals cylinder hole 3 a.

A sealing member 38 aseals piston rod 32 to an upper portion of guide member 34. A sealing member 38 bseals piston rod 32 to a lower portion of guide member 34. A scaling member 38 cseals rod-side cylinder end wall 41 to cylinder hole 3 a. A sealing member 38 dseals piston 40 to cylinder hole 3 a. A sealing member 38 eseals head-side cylinder end wall 43 to cylinder hole 3 a. Collectively, sealing members 38 athrough 38 eallow each hydraulic clamping unit 3 to hydraulically operate without loss of hydraulic fluid.

Referring now to FIG. 4, main cylinder unit 50 of hydraulic clamp device 4 extends vertically through base plate 2. An output member 51 includes a piston rod 52 extending upward from main cylinder unit 50 away from base plate 2. A pivot arm 53 rigidly extends from an end of piston rod 52. Pivot arm 53 allows easy placement of workpiece W. Bolts (not shown) disengagably secure a guide member 54 to the upper surface of base plate 2. During operation, guide member 54 guides piston rod 52 in a clamp-unclamp cycle.

During operation, hydraulic pressure is supplied to oil chamber 83 through second oil path 12 in support device 5. The hydraulic pressure drives piston member 81 upward against the bias from first compression coil spring 84 a. Thereafter, support member 71 moves upward integrally with piston member 81 and bolt 80. Once the end of support member 71 abuts the lower surface of workpiece W, support member 71 stops and piston member 81 and bolt 80 move upward and compresses second compression coil spring 84 b.

Next, hydraulic pressure, increased by hydraulic pressure booster 8, passes through second oil path 13 into oil chamber 78. The now-boosted hydraulic pressures causes elastic sleeve 77 to elastically deform and contract radially, locking support member 71 and causing workpiece W to receive strong support form base plate 2.

Sealing members 85 athrough 85 hoperate to hydraulically seal respective portions of each support device 5, 6 against hydraulic fluid leakage and enable effective supply of hydraulic pressure to support workpiece W.

Referring now to FIG. 6, hydraulic pressure supply device 7 includes a hydraulic pressure pump 92 driven by a motor 91. Hydraulic pressure supply device 7 generates hydraulic pressures in the range of 7 Mpa. Hydraulic pressure supply device 7 also includes an electromagnetic direction switching valve 93 connecting to hydraulic pressure pump 92 along an oil path 90 a.

A first sequence valve 94 is activated at a first pressure setting (e.g., 7 Mpa). First sequence valve 94 connects to an oil path 90 c. Oil path 90 cextends from an oil path 90 baway from direction switching valve 93. Hydraulic pressure supply device 7 also includes a check valve 95 disposed in a bypass oil path 90 fof a first sequence valve 94. A second sequence valve 96 activates at a second pressure setting (e.g., 7 MPa) and connects to first sequence valve 94 along an oil path 90 dand a check valve 97. Check valve 97 is in a bypass oil path 90 gof second sequence valve 96.

A hydraulic pressure pipe 98 aconnects oil path 90 hextending from direction switching valve 93 to first oil path 11 of base plate 2. Hydraulic pressure pipe 98 bconnects oil path 90 bextending from direction switching valve 93 to first oil path 10 of base plate 2. A hydraulic pressure pipe 98 cconnects an oil path 90 iand hydraulic path 90 dto second oil path 12 of base plate 2. A hydraulic pressure pipe 98 dconnects oil path 90 eand hydraulic pressure booster 8.

Hydraulic pressure supply device 7 also includes a control unit (not shown). The control unit controls motor 91, electromagnetic direction switching valve 93, and other components in hydraulic pressure supply device 7.

During operation, direction switching valve 93 provides hydraulic pressure, supplied from hydraulic pressure supply device 7, to the plurality of clamp devices 3, 4 along first unclamping hydraulic path 11. Upon receiving hydraulic pressure, pivot arms 33 pivot to a recessed position at an angle of approximately 70 degrees relative to the clamping position of vertically pivoting clamp devices 3. Additionally, upon receiving hydraulic pressure, pivot arms 53 move to the recessed position by raising and pivoting from the clamping position of horizontally pivoting clamp devices 4. Thus, clamp devices 3, 4 are transferred to into an unclamped state. In this state, operators mount workpiece W and align workpiece W to base plate 2.

After mounting and aligning, direction switching valve 93 is activated, and hydraulic pressure flows from hydraulic pressure supply device 7 to the plurality of clamp devices 3, 4 along first clamping oil path 10 in base plate 2. More specifically, upon receiving hydraulic pressure along first oil path 10, in the vertically pivoting clamp devices 3, pivot arms 33 orient horizontally into a clamping position for clamp device 3, and press workpiece W against base plate 2. Additionally, in horizontally pivoting clamp devices 4, pivot arms 53 pivot and approach workpiece W in a clamping position. Thus, clamp devices 3, 4 enter the clamped state and securely press workpiece W against base plate 2.

During initial clamping operation, the hydraulic pressure applied to first sequence valve 94 from hydraulic pressure supply device 7 does not reach the first pressure setting (e.g., 7 MPa). For this reason, first sequence valve 94 is in a closed state, and hydraulic pressure does not reach oil path 90 d. Once clamp devices 3, 4 clamp workpiece W to base plate 2, the first pressure setting for first sequence valve 94 is reached, and first sequence valve 94 is opens and supplies hydraulic pressure to oil path 90 d.

When hydraulic pressure reaches oil path 90 dthrough first sequence valve 94, hydraulic pressure passes through second oil path 12 to support devices 5, 6. Once support devices 5, 6 receive hydraulic pressure, respective support members 71, 86 rise and abut the lower surface of workpiece W. Up to this point the hydraulic pressure acting on second sequence valve 96 in hydraulic pressure supply device 7 does not reach the second pressure setting (e.g., 7 MPa), and second sequence valve 96 remains in a closed state and does not supply hydraulic pressure supplied to oil path 90 e.

Once support members 71, 86 abut workpiece W, second sequence valve 96 reaches its second pressure setting (e.g., 7 Mpa). Upon reaching the second pressure setting, second sequence valve 96 opens and supplies hydraulic pressure to oil path 90 e. Oil path 90 esupplies hydraulic pressure to hydraulic pressure booster 8 which operates to increase the hydraulic pressure supplied to the plurality of support devices 5, 6 along second oil path 13. Upon receiving the now increased hydraulic pressure, support members 71, 86 of support devices 5, 6 lock firmly and strongly support workpiece W. Once workpiece W is supported by support devices 5, 6 and clamped by clamp devices 3, 4 various machining operations are performed securely, quickly, and with sufficient support to protect, the machining tool, workpiece W, and clamp system 1.

As a further advantage, the hydraulic ports of main cylinder units 30, 50 are easily positioned inside base plate 2 in a simple machining process parallel along the length of base plate 2. Since main cylinder units 30, 50 of clamp devices 3, 4 mount into base plate 2 along the thickness axis of the base plate 2, they easily match with the hydraulic ports and first oil paths 10, 11

Since clamp devices 3, 4 are disposed along the edges of base plate 2, first oil paths 10, 11 can be disposed along a line passing through respective main cylinder units 30, 50 and connect main cylinder units 30, 50 in series. Clamping oil path 10, and unclamping oil path 11 are perpendicular to the surface of base plate 2 and allow a very simple structure. This simple structure makes alternative design and processing easier. Where an alternative workpiece W does not require each clamp device 3, 4, a respective clamp device 3, 4, may be replaced with a simple hydraulic passage unit (not shown) which seals the respective cylinder hole 3 a, 4 aand easily passes hydraulic pressure to the remaining clamp devices 3, 4.

There is no need to form first oil paths 10, 11 at the edges of clamp devices 3, 4 on base plate 2, thus reducing the need for associated space and minimizing size and cost. Since guide members 34, 54 are not integral with hydraulic fluid passage, guide members 34, 54 may be made compact along an axis parallel to the surface of base plate 2 and base plate 2 may be further reduces in size for predetermined workpiece sizes and shapes. This reduction in size, increases a proportion of the work area to the upper surface of base plate 2.

Since the need to provide hydraulic pipes for main cylinder units 30, 50 is eliminated, clamp devices 3, 4 of the clamp system 1 have a simple structure and reduced production costs. Further, since external hydraulic pipes connecting clamp devices 3, 4 are be omitted, system failures caused by damage to hydraulic pipes and obstructions to transporting base plate 2 are eliminated.

Support members 71, 86 are easily arranged by moving compression spring 84 brelative to piston member 81, which is raised directly by hydraulic pressure. As a result, the ends of support members 71, 86 are reliably and quickly abutted against the support points of workpiece W. Thus, workpiece W, is easily and reliably supported against base plate 2 by the plurality of support devices 5, 6. This support, reliably prevents flexure and vibration in workpiece W during machining and improves processing precision.

Main cylinder units 70 of support devices 5, 6 mount directly in the wall of base plate 2 and allow the wall of base plate 2 to effectively serve as a section of main cylinder units 70. Since second oil paths 12, 13 are in the wall of base plate 2, clamp system 1 has an easily formed simple structure thus reducing production costs. Since external hydraulic pipes connecting support devices 5, 6 are eliminated, system failures caused by damage to hydraulic pipes or obstructions to transportation are eliminated.

As a further advantage, hydraulic booster 8 easily provides high hydraulic pressure to the plurality of support devices 5, 6. Hydraulic booster 8 easily increases the hydraulic pressure received from hydraulic pressure supply device 7. As a result, clamp system 1 requires only one hydraulic pressure supply device 7, is reduced in cost, simplified, and increases production efficiency.

During operation, since each output member 31, 51 rotates away from workpiece W, mounting or moving operations for workpiece W are simplified and faster and more efficient production is possible. Individually, output member 31 includes pivot arm 33 pivotably supported at pivot point 33 aand easily rotates away from the clamped position. As a further advantage, support link member 46 supports pivot point 33 aand using a lever-advantage increases and transfers hydraulic force from piston rod 32 to workpiece W while minimizing deflection of pivot arm 33.

A lower end 106 of guide member 105 also forms at least a portion of the rod-side cylinder end wall and further supports guide member 105. Sealing members 107 athrough 107 hhydraulically seal respective members of horizontally pivoting clamp device 4A against hydraulic leakage and enable swift and secure movement. Cylinder cap 101 and guide member 105 may be formed integrally in a further simplification of the present design thus further simplifying assembly, reducing costs, and improving production efficiency.

Referring now to FIG. 9, a hydraulic pressure booster 8C replaces hydraulic pressure booster 8. A main cylinder unit 110 securely mounts to base plate 2. Main cylinder unit 110 includes a cylinder cap 111 and a head-side cylinder end wall 112. Cylinder cap 111 forms a majority of main cylinder unit 110. Head-side cylinder end wall 112 firmly secures to the bottom end of cylinder cap 111.

A hydraulic pressure supply device 7B includes an oil path 117 areceiving hydraulic pressure from the hydraulic pump (not shown in the figure). A pilot hydraulic switching valve 120 is disposed on oil path 117 a. An oil path 117 bconnects oil path 13C of base plate 2 to hydraulic pressure supply device 7B.

A sequence valve 121 is on an oil path 117 c. Oil path 117 cconnects a hydraulic supply port 114 a, on main cylinder unit 110, to sequence valve 121. Sequence valve 121 communicates with oil path 117 aand oil chamber 114 of hydraulic booster 8C. A check valve 122 is disposed in a bypass oil path 117 dof sequence valve 121.

During operation of this embodiment, clamp devices 3, 4 clamp workpiece W to base plate 2. Hydraulic pressure from the hydraulic pump and hydraulic pressure supply device 7B is supplied to support device 5 though oil path 117 band second oil path 13C in base plate 2.

Additionally, while applying an appropriate load to support member 71, hydraulic pressure is supplied to second oil path 12 of the base plate 2 and the support member 71 raises. When support member 71 abuts workpiece W, the hydraulic pressure increases and sequence valve 121, which had been closed opens when the raised hydraulic pressure releases a first pressure setting, thus causing hydraulic pressure to enter hydraulic pressure booster 8C.

As hydraulic pressure booster 8C receives hydraulic pressure, piston member 113 activates and the hydraulic pressure is increased in booster chamber 115. Oil path 13 ctransports the now-boosted hydraulic pressure to support device 5, and support member 71 firmly locks and supports workpiece W.

Referring now to FIG. 10, in a hydraulic pressure booster 8D, cylinder cap 111 of hydraulic pressure booster 8 is eliminated. A hole (not labeled) is in base plate 2 and securely mounts main cylinder unit 110D in the wall of base plate 2. In this embodiment, small-diameter piston 113 bprojects into booster chamber 115D above the head-side cylinder wall, and booster chamber 115D connects to oil path 13D.

Referring now to FIG. 11, a hydraulic pressure supply device 7E includes a hydraulic pump 132 driven by a motor 131. Hydraulic pump 132 and motor 131 operate to provide a hydraulic pressure (e.g., 7 Mpa) to clamping system 1. An oil path 130 aconnects an electromagnetic switching valve 133 connects to hydraulic pump 132. An oil path 130 bconnects an electromagnetic direction switching valve 134 to hydraulic pump 132. An oil path 130 cand an oil path 130 dconnect a sequence valve 135 to direction switching valve 134. Sequence valve 135 activates at a first pressure setting (e.g., 7 Mpa). A check valve 136 is disposed in a bypass oil path 130 fof sequence valve 135.

A pair of oil paths 130 g, 130 hextend from direction switching valve 133 and connect to respective first oil paths 10, 11 in base plate 2. An oil path 130 iextends from oil paths 130 c, 130 dand connects to second oil path 12 of base plate 2. Oil path 130 eextends from sequence valve 135 to hydraulic booster 8.

During operation, when direction switching valve 134 is switched to release hydraulic pressure, direction switching valve 133 is controlled, and first oil path 10 passes hydraulic pressure from hydraulic pressure supply device 7E to clamp devices 3.

Clamp devices 3 receive the hydraulic pressure and enter the clamped state and secure workpiece W to base plate 2. Once workpiece W is clamped, direction switching valve 134 is controlled supplies hydraulic pressure to oil path 130 c.

Oil path 130 cpasses hydraulic pressure through second oil path 12 and base plate 2 to support devices 5, 6. The hydraulic pressure causes support members 71, 86 to rise and abut the lower surface of workpiece W. Once support members 71, 86 reach workpiece W, the first pressure setting is applied to sequence valve 135. Upon reaching the first pressure setting, sequence valve 135 opens and supplies hydraulic pressure to hydraulic pressure booster 8. Hydraulic pressure booster 8 increases the hydraulic pressure, and returns the now-boosted hydraulic pressure through second oil path 13 to support devices 5, 6.

In an alternative embodiment, alternative clamping devices other than clamp devices 3, 4, 4A, 4B may be used as the hydraulic clamp devices, and the main cylinder units of these alternative clamping devices may be mounted on the thickness axis of base plate 2.

In understanding hydraulic pressure delivery to clamp devices 3, 4 through first oil paths 10, 11, it should be understood, that the delivery of hydraulic pressure downstream from hydraulic pressure supply device 7, where identified as ‘in series,’ is substantially in series through each respective clamp device 3, 4 (see FIGS. 2 and 6) despite clamp devices 3, 4 being separated in different rows, each row is supplied simultaneously in series. In other words, in each row, if a single clamp device 3, 4 fails to pass hydraulic pressure, there is no passage beyond the failed device.

It understanding hydraulic pressure delivery to support devices 5, 6 through second oil paths 12, 13, it should be understood, that the delivery of regular and boosted hydraulic pressure downstream from hydraulic pressure supply device 7 and hydraulic pressure booster 8, where identified as ‘in parallel,’ is substantially in parallel from a common supply line between each respective support device 5, 6 (see FIGS. 2 and 6) despite the individual physical arrangement of support devices 5, 6.

Hydraulic pumps are vital to the role of heavy equipment such as excavators, tractors, forklifts and cranes. The hydraulic pump converts mechanical energy into hydraulic energy through the movement of the fluid in the conveying pipeline, thereby driving the equipment to work. It can determine the effectiveness of these devices on the job site. If the hydraulic pump fails or runs below an acceptable level, it needs to be repaired immediately to avoid sudden equipment shutdowns and greater losses.

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