Potwierdzono

Characteristics/Applications
- Not Applicable
Module
- 1
Length L(mm)
[20–980/1mm jedn.]
Material
General Steel Material
EN 1.1191 Equiv.
Material Details
- EN 1.1191 Equiv.
Surface Treatment
- Black Oxide
Tooth Width W (or D)(mm)
- 10
Hole Machining
- Z (Side Counterbored)
Hole Position (First) [A](mm)
[5–15/1mm jedn.]
Type
- RGEAL
CAD
- 2D
- 3D
Szacowane dni wysyłki
- Wszystko
- W ciągu 7 dni robocze

Dodatkowa opcje

Hole Position [B] / Hole Pitch [B](mm)
[7–35/1mm jedn.]
One End Tapped Machining [MC](mm)
- 3
- 4
Both Ends Tapped Machining [WMC](mm)
- 3
- 4
Hole Position [D](mm)
[7–975/1mm jedn.]

Rack gears / contact angle 20 degrees / dimension L configurable (RGEAL1.0Z-50-A10-B30)

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KatalogS. 1-1532

Przestroga

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Numer części:

RGEAL1.0Z-50-A10-B30

Wyczyść

Rysunek konturowy i tabela specyfikacji
Lista numerów części
Szczegółowe informacje
Katalog

Rysunek konturowy i tabela specyfikacji

Dimensional Drawing

Specification Table

Alterations (Optional)

Dimensional Drawing

Hole Machining N: No Hole Machining

Hole machining KA: Side Through Hole

Hole Machining HT: Back Tapped

Hole Machining ST: Side Tapped

Hole Machining Z: Side Counterbored

Hole Machining N: No Hole Machining

Hole machining KA: Side Through Hole

Hole Machining HT: Back Tapped

Hole Machining ST: Side Tapped

Hole Machining Z: Side Counterbored

■ Hole Position Configurable Type (Number of Holes is up to 4)

■ Number of Holes Configurable Type

Enlarged View of End Face

Module	P Tolerance
0.5 to 2.0	－0.1 －0.3
2.5·3.0	－0.1 －0.4

■Hole Position Configurable Type

Module	M (Coarse)	d₁	d₂	Z₁
0.5	—	3.5	—	—
0.8	—	3.5	—	—
1.0	M3	3.5	6.5	3.5
1.5	M4	4.5	8	4.5
2.0	M5	5.5	9.5	5.5
2.5	M6	6.5	11	6.5
3.0	M8	9	14	9

■ Number of Holes Configurable Type

Module	M (Coarse)	d₁	d₂	Z₁
0.5	—	3.5	—	—
0.8	—	3.5	—	—
1.0	M3	3.5	6.5	3.5
1.5	M5	5.5	9.5	5.5
2.0	M6	6.5	11	6.5
2.5	M8	9	14	9
3.0	M10	11	17.5	11

[ ! ] Up to four holes can be specified.
[ ! ]A+B+C+D ≤ L－5

　　　　[ ! ] F = L－B× (K－1)2 ≥ 15

Metal: L Tolerance (mm)

Plastic: L Tolerance (mm)

W, H Dimension Tolerance (mm)

Accumulated Pitch Error (μm)

Module	Tolerance
0.5 to 2.0	-0.2 to -0.6
2.5 to 3.0	-0.2 to -0.8

Overall Length (L)	Tolerance
Overall Length (L)	Tolerance
50 to 100	±1.2
101 to 200	±1.4
201 to 300	±1.6
301 to 400	±1.8
401 to 500	±2.0
501 to 600	±2.2
601 to 700	±2.4
701 to 800	±2.6
801 to 900	±2.8
901 to 1000	±3.0

Standard Dimension Range (mm)		Tolerance
Over	or Less	Tolerance
0	5	0 to -0.18
6	10	0 to -0.22
11	18	0 to -0.27
19	30	0 to -0.33
31	50	0 to -0.39

Module	Nominal, Overall Length L
Module	Up to 100	101 to 300	301 to 500	501 to 1000
0.5 to 1.5	54 (76)	65 (92)	72 (101)	100 (117)
2.0 to 3.0	62 (86)	73 (102)	80 (112)	91 (128)

[ ! ] Values in ( ) are for RGEASL, RGEAML, RGEAPL

[ ! ] Dimensions may change depending on temperature and humidity.

Type		[M] Material	[S] Surface Treatment
Hole Position Configurable Type	Number of Holes Configurable Type	[M] Material	[S] Surface Treatment
RGEAL	LRGEA	EN 1.1191 Equiv.	Black Oxide
RGEABL	LRGEAB	Free-cutting brass	-
RGEASL	LRGEAS	EN 1.4301 Equiv.	-
RGEAML	LRGEAM	MC Nylon (Blue)	-
RGEAPL	LRGEAP	Polyacetal (White)	-

[ ! ] Cut surface and machined surface are not surface treated.
[!] Material: MC Nylon and Polyacetal dimensions may change depending on the operating environment.
[!] Flatness (warpage) accuracy is L = 500 or less: 0.2, 501 or more: 0.3.
[!] This product is not hardened.

Specification Table

Part Number	—	L (Overall Length)	—	Hole Position (First)	—	Hole Position (Second)	—	Hole Position (Third)
RGEAML1.0Z	—	450	—	A50	—	B150	—	C150

Part Number	—	L (Overall Length)	—	K (Number of Holes)	—	B (Hole Pitch)
LRGEA2.0ST	—	900	—	K8	—	B80

■ Hole Position Configurable Type (Number of Holes is up to 4)

Part Number			Overall Length	Hole Position	P (Pitch)	W	H	h
Part Number			L	ABC
Type	Module	Hole Machining	Unit: mm	Unit: mm
(EN 1.1191 Equiv.) RGEAL (EN 1.4301 Equiv.) RGEASL (Polyacetal) RGEAPL	0.5	N (No Hole Machining) KA (Side Through Hole)	20 to 480	5 to 475	1.571	3	9	8.5
	0.8	N (No Hole Machining) KA (Side Through Hole)	20 to 480	5 to 475	2.513	4	10	9.2
	1.0	N (No Hole Machining) HT (Back Tapped) ST (Side Tapped) Z (Side Counterbored)	20 to 980	5 to 975	3.142	10	12 (10)	11 (9)
	1.5				4.712	15	20 (15)	18.5 (13.5)
	2.0				6.283	20	25 (20)	23 (18)
	2.5				7.854	25	30 (25)	27.5 (22.5)
	3.0				9.425	30	35 (30)	32 (27)
(Free-Cutting Brass) RGEABL (MC Nylon) RGEAML	0.5	N (No Hole Machining) KA (Side Through Hole)	20 to 280	5 to 275	1.571	3	9	8.5
	0.8	N (No Hole Machining) KA (Side Through Hole)	20 to 280	5 to 275	2.513	4	10	9.2
	1.0	N,HT,ST,Z	20 to 480	5 to 475	3.142	10	12	11

[ ! ] H,h () is the value for EN 1.4301 Equiv..

■Number of Holes Configurable Type (Hole pitch configurable / equal distribution)

Part Number			Overall Length	K	B	P (Pitch)	W	H	h
Part Number			L	(Number of Holes)	(Hole Pitch)
Type	Module	Hole Machining	Unit: mm		Unit: mm
(EN 1.1191 Equiv.) LRGEA (EN 1.4301 Equiv.) LRGEAS (Polyacetal) LRGEAP	0.5	N (No Hole Machining) KA (Side Through Hole)	20 to 480	2 to 8	50 to 450	1.571	3	9	8.5
	0.8	N (No Hole Machining) KA (Side Through Hole)	20 to 480	2 to 8	50 to 450	2.513	4	10	9.2
	1.0	N (No Hole Machining) HT (Back Tapped) ST (Side Tapped) Z (Side Counterbored)	20 to 980	2 to 12	50 to 500	3.142	10	12 (10)	11 (9)
	1.5					4.712	15	20 (15)	18.5 (13.5)
	2.0					6.283	20	25 (20)	23 (18)
	2.5					7.854	25	30 (25)	27.5 (22.5)
	3.0					9.425	30	35 (30)	32 (27)
(Free-Cutting Brass) LRGEAB (MC Nylon) LRGEAM	0.5	N (No Hole Machining) KA (Side Through Hole)	20 to 280	2 to 5	50 to 280	1.571	3	9	8.5
	0.8	N (No Hole Machining) KA (Side Through Hole)	20 to 280	2 to 5	50 to 280	2.513	4	10	9.2
	1.0	N,HT,ST,Z	20 to 480	2 to 8	50 to 480	3.142	10	12	11

[ ! ] H,h () is the value for EN 1.4301 Equiv..

Alterations

One End Tapped

Both Ends Tapped

Tapped Hole Dimension Change

Code

WMC

TPC

Spec.

Ordering Code MC5

Ordering Code WMC5

Changes the tapped hole dimension.
Ordering Code TPC4

	M	TPC
	M3	M4
	M4	M3 M5
	M5	M4 M6
	M6	M5 M8
	M8	M6

Module	M Selection
1.0	3	4
1.5 to 3.0		4	5	6

Module	M Selection
1.0	3	4
1.5 to 3.0		4	5	6

[NG] For RGEAS, M4 is not available for module 1.0.

General information - Rack Gears

Rack gear product assortment - steel rack gear - stainless steel rack gear - brass rack gear - plastic rack gear - hardened rack gear

Selection Details of Rack Gears

-Material: steel, stainless steel, brass, plastic

-Coatings: uncoated, burnished

-Heat treatment: untreated, surface curing (induction hardened)

-Module: 0.5, 0.8, 1, 1.5, 2, 2.5, 3

-Width: 3 to 30 mm

-Number of teeth: 9 to 192

-Outer diameter (round): 8 to 30 mm

-Length: 20 to 1980 mm

Description / Rack Gear Basics

The rack gear from MISUMI are fundamentally used for motion conversion. The rack gear allows converting a rotary motion into a linear motion or a linear motion into a rotary motion. A rack gear can transmit high forces due to the form-fitting gearing. In connection with a gear wheel or spur gear, a gear rack drive forms a slip-free transmission of force and prevents a slip-through. For a large number of applications, the slip-free transmission of the rack gear is an efficient transmission of force and motion. The rack gear drive also withstands high loads with a compact design. With rack gears, high speeds can also be driven in applications with low noise generation. With MISUMI, you can configure your rack gears individually in length and in other parameters.

During the transfer of motion, the teeth intertwine and largely unroll during the transfer to one another. The rack gear can be used for the transfer of motion almost over the entire length. To prevent the gear wheel from overflowing, for example, stopper bolts or stopper blocks are recommended. Since the module is standardized, it must be ensured for the construction of a rack drive that the same module is used for the rack and the gear wheel. The rack gear allows precise control by directly transmitting motion, torque and speed.

For high wear resistance and reliability, our product range also offers surface-hardened rack gears. The hardened rack gear has a harder surface of the teeth, which makes it less susceptible to wear and tear. Their long service life helps reduce production downtime. Hardened rack gears are also less susceptible to locking-related play and retain their precision in the long term. This aspect makes hardened rack gears particularly recommended for precise applications.

A rack gear drive has a low backlash. In general, the tooth flank clearance is used for assembly and thermal expansion. Like the head play, it can serve as a gap for lubricants. For very precise applications, the reverse play is not beneficial. In order to minimize this during precision applications, pre-tensioning is required. On lifting tables, the dead weight already generates a vertical pretension in the rack gear, which minimizes the reverse play. If the rack gear is aligned horizontally, a separate pretension should be used to reduce the reverse play. This can be achieved with tension springs or other exciting components, for example. When selecting a suitable rack gear, the first decision criterion is the material of the rack gear drive. The following are some advantages of the rack gear materials:

Steel rack gears

Rack gears made of steel have high strength and withstand high loads. Therefore, steel rack gears are suitable for heavy loads. The material surface can be hardened to increase wear resistance. This makes the rack gear resistant and durable. In addition, steel is very heat-resistant and is suitable for applications in which high ambient temperatures occur. One disadvantage of steel is its low corrosion resistance.

Stainless steel rack gears

Stainless steel rack gears are highly corrosion resistant, since stainless steel forms a passive layer (oxide layer). This makes them suitable for applications where higher humidity is found. Furthermore, stainless steel offers good chemical resistance. Like steel, stainless steel is temperature resistant without losing strength. High temperatures can cause discoloration (tempering colour) in stainless steel. However, this does not affect the function in any way. Similar to the steel, stainless steel is robust and has a long service life. Another advantage is that rack gears made of stainless steel have hygienic properties. Therefore, this material is often used in the pharmaceutical industry and in medical technology.

Brass rack gears

Brass rack gears are well protected against corrosion. Therefore, a brass rack gear is well suited in corrosive environments. Depending on the application, it can be advantageous that brass does not tend to spark when abrasion is applied. In addition, brass has a high strength and ductility. This allows the material to deform before it breaks. Brass rack gears have a high thermal conductivity, which allows heat to be dissipated similar to a heat sink. The perhaps most important property of the brass rack gear is its gliding property. In the case of a lubrication film dissipates, this property serves as a certain fail-safe.

Lubrication of rack gears

The lubrication of the rack gear is decisive for low-wear operation. The lubrication reduces the friction on the tooth flanks of the rack gear and the pinion, which reduces the material abrasion. In this way, proper lubrication of the rack gear increases the service life, performance and ensures long-term precision. In principle, a rack can be lubricated with grease or oil. The type of lubrication that is suitable depends on several factors such as temperature, load and speed. Grease lubrication is often used for high loads and torques, while oil lubrication is used for high speeds. Lubricant manufacturers offer a suitable lubricant for almost all load cases. Before re-lubricating, the tooth drive should be thoroughly cleaned to prevent damage to the tooth flanks or teeth from contamination. Depending on the application, the lubricant can be sprayed, brushed, or sprayed onto the rack gear. The lubrication intervals must be selected depending on the application and the lubricant used. It is always recommended to adjust the lubrication intervals to the given circumstances.